/*++
Copyright (c) 2006 Microsoft Corporation

Module Name:

    ast.cpp

Abstract:

   Expression DAG

Author:

    Leonardo de Moura (leonardo) 2006-09-28.

Revision History:

--*/
#include<sstream>
#include"ast.h"
#include"ast_pp.h"
#include"ast_ll_pp.h"
#include"buffer.h"
#include"warning.h"
#include"string_buffer.h"
#include"ast_util.h"
#include"ast_smt2_pp.h"

// -----------------------------------
//
// parameter
//
// -----------------------------------

parameter::~parameter() {
    if (m_kind == PARAM_RATIONAL) {
        reinterpret_cast<rational *>(m_rational)->~rational();
    }
}

parameter::parameter(parameter const& other) {
    m_kind = PARAM_INT;
    m_int = 0;
    *this = other;
}

parameter& parameter::operator=(parameter const& other) {
    if (this == &other) {
        return *this;
    }
    if (m_kind == PARAM_RATIONAL) {
        reinterpret_cast<rational *>(m_rational)->~rational();
    }
    m_kind = other.m_kind;
    switch(other.m_kind) {
    case PARAM_INT: m_int = other.get_int(); break;
    case PARAM_AST: m_ast = other.get_ast(); break;
    case PARAM_SYMBOL: new (m_symbol) symbol(other.get_symbol()); break;
    case PARAM_RATIONAL: new (m_rational) rational(other.get_rational()); break;
    case PARAM_DOUBLE: m_dval = other.m_dval; break;
    case PARAM_EXTERNAL: m_ext_id = other.m_ext_id; break;
    default:
        UNREACHABLE();
        break;
    }
    return *this;
}

void parameter::init_eh(ast_manager & m) {
    if (is_ast()) {
        m.inc_ref(get_ast());
    }
}

void parameter::del_eh(ast_manager & m, family_id fid) {
    if (is_ast()) {
        m.dec_ref(get_ast());
    }
    else if (is_external()) {
        SASSERT(fid != null_family_id);
        m.get_plugin(fid)->del(*this);
    }
}

bool parameter::operator==(parameter const & p) const { 
    if (m_kind != p.m_kind) return false;
    switch(m_kind) {
    case PARAM_INT: return m_int == p.m_int;
    case PARAM_AST: return m_ast == p.m_ast;
    case PARAM_SYMBOL: return get_symbol() == p.get_symbol();
    case PARAM_RATIONAL: return get_rational() == p.get_rational();
    case PARAM_DOUBLE: return m_dval == p.m_dval;
    case PARAM_EXTERNAL: return m_ext_id == p.m_ext_id;
    default: UNREACHABLE(); return false;
    }
}

unsigned parameter::hash() const {
    unsigned b = 0;
    switch(m_kind) {
    case PARAM_INT:      b = m_int; break;
    case PARAM_AST:      b = m_ast->hash(); break;
    case PARAM_SYMBOL:   b = get_symbol().hash(); break;
    case PARAM_RATIONAL: b = get_rational().hash(); break;
    case PARAM_DOUBLE:   b = static_cast<unsigned>(m_dval); break;
    case PARAM_EXTERNAL: b = m_ext_id; break;
    }
    return (b << 2) | m_kind;
}

std::ostream& parameter::display(std::ostream& out) const {
    switch(m_kind) {
    case PARAM_INT:      return out << get_int();
    case PARAM_SYMBOL:   return out << get_symbol();
    case PARAM_RATIONAL: return out << get_rational();
    case PARAM_AST:      return out << "#" << get_ast()->get_id();
    case PARAM_DOUBLE:   return out << m_dval;
    case PARAM_EXTERNAL: return out << "@" << m_ext_id;
    default:
        UNREACHABLE();
        return out << "[invalid parameter]";
    }
}

void display_parameters(std::ostream & out, unsigned n, parameter const * p) {
    if (n > 0) {
        out << "[";
        for (unsigned i = 0; i < n; i ++)
            out << p[i] << (i < n-1 ? ":" : "");
        out << "]";
    }
}

// -----------------------------------
//
// family_manager
//
// -----------------------------------

family_id family_manager::mk_family_id(symbol const & s) {
    family_id r; 
    if (m_families.find(s, r)) {
        return r;
    }
    r = m_next_id;
    m_next_id++;
    m_families.insert(s, r);
    m_names.push_back(s);
    return r;
}

family_id family_manager::get_family_id(symbol const & s) const {
    family_id r; 
    if (m_families.find(s, r))
        return r;
    else
        return null_family_id;
}

bool family_manager::has_family(symbol const & s) const {
    return m_families.contains(s);
}

// -----------------------------------
//
// decl_info
//
// -----------------------------------

decl_info::decl_info(family_id family_id, decl_kind k, unsigned num_parameters, 
                     parameter const * parameters, bool private_params):
    m_family_id(family_id),
    m_kind(k),
    m_parameters(num_parameters, const_cast<parameter *>(parameters)),
    m_private_parameters(private_params) {
}

decl_info::decl_info(decl_info const& other) :
    m_family_id(other.m_family_id),
    m_kind(other.m_kind),
    m_parameters(other.m_parameters.size(), other.m_parameters.c_ptr()),
    m_private_parameters(other.m_private_parameters) {    
}


void decl_info::init_eh(ast_manager & m) {
    vector<parameter>::iterator it  = m_parameters.begin();
    vector<parameter>::iterator end = m_parameters.end();
    for (; it != end; ++it) {
        it->init_eh(m);
    }
}

void decl_info::del_eh(ast_manager & m) {
    vector<parameter>::iterator it  = m_parameters.begin();
    vector<parameter>::iterator end = m_parameters.end();
    for (; it != end; ++it) {
        it->del_eh(m, m_family_id);
    }
}

struct decl_info_child_hash_proc {
    unsigned operator()(decl_info const * info, unsigned idx) const { return info->get_parameter(idx).hash(); }
};

unsigned decl_info::hash() const {
    unsigned a = m_family_id;
    unsigned b = m_kind;
    unsigned c = get_num_parameters() == 0 ? 0 : get_composite_hash<decl_info const *, default_kind_hash_proc<decl_info const *>, decl_info_child_hash_proc>(this, get_num_parameters());
    mix(a, b, c);
    return c;
}

bool decl_info::operator==(decl_info const & info) const {
    return m_family_id == info.m_family_id && m_kind == info.m_kind && 
        compare_arrays<parameter>(m_parameters.begin(), info.m_parameters.begin(), m_parameters.size());
}

std::ostream & operator<<(std::ostream & out, decl_info const & info) {
    out << ":fid " << info.get_family_id() << " :decl-kind " << info.get_decl_kind() << " :parameters (";
    for (unsigned i = 0; i < info.get_num_parameters(); i++) {
        if (i > 0) out << " ";
        out << info.get_parameter(i);
    }
    out << ")";
    return out;
}

// -----------------------------------
//
// sort_size
//
// -----------------------------------

std::ostream& operator<<(std::ostream& out, sort_size const & ss) {
    if (ss.is_infinite()) { return out << "infinite"; }
    else if (ss.is_very_big()) { return out << "very-big"; }
    else { SASSERT(ss.is_finite()); return out << ss.size(); }
}

// -----------------------------------
//
// sort_info
//
// -----------------------------------
std::ostream & operator<<(std::ostream & out, sort_info const & info) {
    operator<<(out, static_cast<decl_info const&>(info));
    out << " :size " << info.get_num_elements();
    return out;
}

// -----------------------------------
//
// func_decl_info
//
// -----------------------------------

func_decl_info::func_decl_info(family_id family_id, decl_kind k, unsigned num_parameters, parameter const * parameters):
    decl_info(family_id, k, num_parameters, parameters),
    m_left_assoc(false),
    m_right_assoc(false),
    m_flat_associative(false),
    m_commutative(false),
    m_chainable(false),
    m_pairwise(false),
    m_injective(false),
    m_idempotent(false),
    m_skolem(false) {
}

bool func_decl_info::operator==(func_decl_info const & info) const {
    return decl_info::operator==(info) && 
        m_left_assoc == info.m_left_assoc && 
        m_right_assoc == info.m_right_assoc && 
        m_flat_associative == info.m_flat_associative &&
        m_commutative == info.m_commutative && 
        m_chainable == info.m_chainable &&
        m_pairwise == info.m_pairwise && 
        m_injective == info.m_injective &&
        m_skolem == info.m_skolem;
}

std::ostream & operator<<(std::ostream & out, func_decl_info const & info) {
    operator<<(out, static_cast<decl_info const&>(info));
    out << " :left-assoc " << info.is_left_associative();
    out << " :right-assoc " << info.is_right_associative();
    out << " :flat-associative " << info.is_flat_associative();
    out << " :commutative " << info.is_commutative();
    out << " :chainable " << info.is_chainable();
    out << " :pairwise " << info.is_pairwise();
    out << " :injective " << info.is_injective();
    out << " :idempotent " << info.is_idempotent();
    out << " :skolem " << info.is_skolem();
    return out;
}

// -----------------------------------
//
// ast
//
// -----------------------------------

static char const * g_ast_kind_names[] = {"application", "variable", "quantifier", "sort", "function declaration" };

char const * get_ast_kind_name(ast_kind k) {
    return g_ast_kind_names[k];
}

// -----------------------------------
//
// func_decl
//
// -----------------------------------

func_decl::func_decl(symbol const & name, unsigned arity, sort * const * domain, sort * range, func_decl_info * info):
    decl(AST_FUNC_DECL, name, info),
    m_arity(arity),
    m_range(range) {
    if (arity != 0)
        memcpy(const_cast<sort **>(get_domain()), domain, sizeof(sort *) * arity);
}

// -----------------------------------
//
// application
//
// -----------------------------------

static app_flags mk_const_flags() {
    app_flags r;
    r.m_depth           = 1;
    r.m_ground          = true;
    r.m_has_quantifiers = false;
    r.m_has_labels      = false;
    return r;
}

static app_flags mk_default_app_flags() {
    app_flags r;
    r.m_depth           = 1;
    r.m_ground          = true;
    r.m_has_quantifiers = false;
    r.m_has_labels      = false;
    return r;
}

app_flags app::g_constant_flags = mk_const_flags();

app::app(func_decl * decl, unsigned num_args, expr * const * args):
    expr(AST_APP),
    m_decl(decl),
    m_num_args(num_args) {
    for (unsigned i = 0; i < num_args; i++)
        m_args[i] = args[i];
}

// -----------------------------------
//
// quantifier
//
// -----------------------------------

quantifier::quantifier(bool forall, unsigned num_decls, sort * const * decl_sorts, symbol const * decl_names, expr * body,
                       int weight, symbol const & qid, symbol const & skid, unsigned num_patterns, expr * const * patterns,
                       unsigned num_no_patterns, expr * const * no_patterns):
    expr(AST_QUANTIFIER),
    m_forall(forall),
    m_num_decls(num_decls),
    m_expr(body),
    m_depth(::get_depth(body) + 1),
    m_weight(weight),
    m_has_unused_vars(true),
    m_has_labels(::has_labels(body)),
    m_qid(qid),
    m_skid(skid),
    m_num_patterns(num_patterns),
    m_num_no_patterns(num_no_patterns) {
    SASSERT(m_num_patterns == 0 || m_num_no_patterns == 0);

    memcpy(const_cast<sort **>(get_decl_sorts()), decl_sorts, sizeof(sort *) * num_decls);
    memcpy(const_cast<symbol*>(get_decl_names()), decl_names, sizeof(symbol) * num_decls);
    if (num_patterns != 0)
        memcpy(const_cast<expr **>(get_patterns()), patterns, sizeof(expr *) * num_patterns);
    if (num_no_patterns != 0)
        memcpy(const_cast<expr **>(get_no_patterns()), no_patterns, sizeof(expr *) * num_no_patterns);
}

// -----------------------------------
//
// Auxiliary functions
//
// -----------------------------------

sort * get_sort(expr const * n) {
    while (true) {
        switch(n->get_kind()) {
        case AST_APP: 
            return to_app(n)->get_decl()->get_range();
        case AST_VAR:
            return to_var(n)->get_sort();
        case AST_QUANTIFIER:
            // The sort of the quantifier is the sort of the nested expression.
            // This code assumes the given expression is well-sorted.
            n = to_quantifier(n)->get_expr();
            break;
        default:
            UNREACHABLE();
            return 0;
        }
    }
}

// -----------------------------------
//
// AST hash-consing
//
// -----------------------------------

unsigned get_node_size(ast const * n) {
    switch(n->get_kind()) {
    case AST_SORT:       return to_sort(n)->get_size();
    case AST_FUNC_DECL:  return to_func_decl(n)->get_size();
    case AST_APP:        return to_app(n)->get_size();
    case AST_VAR:        return to_var(n)->get_size();
    case AST_QUANTIFIER: return to_quantifier(n)->get_size();
    default: UNREACHABLE();
    }
    return 0;
}    

bool compare_nodes(ast const * n1, ast const * n2) {
    if (n1->get_kind() != n2->get_kind()) {
        return false;
    }
    switch (n1->get_kind()) {
    case AST_SORT:
        if ((to_sort(n1)->get_info() == 0) != (to_sort(n2)->get_info() == 0)) {
            return false;
        }
        if (to_sort(n1)->get_info() != 0 && !(*to_sort(n1)->get_info() == *to_sort(n2)->get_info())) {
            return false;
        }
        return to_sort(n1)->get_name()  == to_sort(n2)->get_name();
    case AST_FUNC_DECL:
        if ((to_func_decl(n1)->get_info() == 0) != (to_func_decl(n2)->get_info() == 0)) {
            return false;
        }
        if (to_func_decl(n1)->get_info() != 0 && !(*to_func_decl(n1)->get_info() == *to_func_decl(n2)->get_info())) {
            return false;
        }
        return
            to_func_decl(n1)->get_name()  == to_func_decl(n2)->get_name() &&
            to_func_decl(n1)->get_arity() == to_func_decl(n2)->get_arity() &&
            to_func_decl(n1)->get_range() == to_func_decl(n2)->get_range() &&
            compare_arrays(to_func_decl(n1)->get_domain(), 
                           to_func_decl(n2)->get_domain(),
                           to_func_decl(n1)->get_arity());
    case AST_APP:
        return 
            to_app(n1)->get_decl()     == to_app(n2)->get_decl() &&
            to_app(n1)->get_num_args() == to_app(n2)->get_num_args() &&
            compare_arrays(to_app(n1)->get_args(), to_app(n2)->get_args(), to_app(n1)->get_num_args());
    case AST_VAR:
        return 
            to_var(n1)->get_idx()  == to_var(n2)->get_idx() &&
            to_var(n1)->get_sort() == to_var(n2)->get_sort();
    case AST_QUANTIFIER:
        return 
            to_quantifier(n1)->is_forall()           == to_quantifier(n2)->is_forall() &&
            to_quantifier(n1)->get_num_decls()       == to_quantifier(n2)->get_num_decls() &&
            compare_arrays(to_quantifier(n1)->get_decl_sorts(),
                           to_quantifier(n2)->get_decl_sorts(),
                           to_quantifier(n1)->get_num_decls()) &&
            to_quantifier(n1)->get_expr()            == to_quantifier(n2)->get_expr() && 
            to_quantifier(n1)->get_weight()          == to_quantifier(n2)->get_weight() &&            
            to_quantifier(n1)->get_num_patterns() == to_quantifier(n2)->get_num_patterns() &&
            compare_arrays(to_quantifier(n1)->get_patterns(), 
                           to_quantifier(n2)->get_patterns(),
                           to_quantifier(n1)->get_num_patterns()) &&
            to_quantifier(n1)->get_num_no_patterns() == to_quantifier(n2)->get_num_no_patterns() &&            
            compare_arrays(to_quantifier(n1)->get_no_patterns(),
                           to_quantifier(n2)->get_no_patterns(),
                           to_quantifier(n1)->get_num_no_patterns());
    default:
        UNREACHABLE();
    }
    return false;
}

template<typename T>
inline unsigned ast_array_hash(T * const * array, unsigned size, unsigned init_value) {
    if (size == 0)
        return init_value;
    switch (size) {
    case 1:
        return combine_hash(array[0]->hash(), init_value);
    case 2:
        return combine_hash(combine_hash(array[0]->hash(), array[1]->hash()),
                            init_value);
    case 3:
        return combine_hash(combine_hash(array[0]->hash(), array[1]->hash()),
                            combine_hash(array[2]->hash(), init_value));
    default: {
        unsigned a, b, c;
        a = b = 0x9e3779b9;
        c = init_value;    
        while (size >= 3) {
            size--;
            a += array[size]->hash();
            size--;
            b += array[size]->hash();
            size--;
            c += array[size]->hash();
            mix(a, b, c);
        }
        switch (size) {
        case 2:
            b += array[1]->hash();
            Z3_fallthrough;
        case 1:
            c += array[0]->hash();
        }
        mix(a, b, c);
        return c;
    } }
}

unsigned get_asts_hash(unsigned sz, ast * const* ns, unsigned init) {
    return ast_array_hash<ast>(ns, sz, init);
}
unsigned get_apps_hash(unsigned sz, app * const* ns, unsigned init) {
    return ast_array_hash<app>(ns, sz, init);    
}
unsigned get_exprs_hash(unsigned sz, expr * const* ns, unsigned init) {
    return ast_array_hash<expr>(ns, sz, init);
}
unsigned get_sorts_hash(unsigned sz, sort * const* ns, unsigned init) {
    return ast_array_hash<sort>(ns, sz, init);
}
unsigned get_decl_hash(unsigned sz, func_decl* const* ns, unsigned init) {
    return ast_array_hash<func_decl>(ns, sz, init);
}

unsigned get_node_hash(ast const * n) {
    unsigned a, b, c;
    
    switch (n->get_kind()) {
    case AST_SORT:
        if (to_sort(n)->get_info() == 0) 
            return to_sort(n)->get_name().hash();
        else
            return combine_hash(to_sort(n)->get_name().hash(), to_sort(n)->get_info()->hash());
    case AST_FUNC_DECL:
        return ast_array_hash(to_func_decl(n)->get_domain(), to_func_decl(n)->get_arity(), 
                              to_func_decl(n)->get_info() == 0 ? 
                              to_func_decl(n)->get_name().hash() : combine_hash(to_func_decl(n)->get_name().hash(), to_func_decl(n)->get_info()->hash()));
    case AST_APP:
        return ast_array_hash(to_app(n)->get_args(), 
                              to_app(n)->get_num_args(),
                              to_app(n)->get_decl()->hash());
    case AST_VAR:
        return combine_hash(to_var(n)->get_idx(), to_var(n)->get_sort()->hash());
    case AST_QUANTIFIER:
        a = ast_array_hash(to_quantifier(n)->get_decl_sorts(),
                           to_quantifier(n)->get_num_decls(),
                           to_quantifier(n)->is_forall() ? 31 : 19);
        b = to_quantifier(n)->get_num_patterns();
        c = to_quantifier(n)->get_expr()->hash();
        mix(a,b,c);
        return c;
    default:
        UNREACHABLE();
    }
    return 0;
}

void ast_table::erase(ast * n) {
    // Customized erase method
    // It uses two important properties:
    // 1. n is known to be in the table.
    // 2. operator== can be used instead of compare_nodes (big savings)
    unsigned mask = m_slots - 1;
    unsigned h    = n->hash();
    unsigned idx  = h & mask;
    cell * c      = m_table + idx;
    SASSERT(!c->is_free());
    cell * prev = 0;
    while (true) {
        if (c->m_data == n) {
            m_size--;
            if (prev == 0) {
                cell * next = c->m_next;
                if (next == 0) {
                    m_used_slots--;
                    c->mark_free();
                    SASSERT(c->is_free());
                }
                else {
                    *c = *next;
                    recycle_cell(next);
                }
            }
            else {
                prev->m_next = c->m_next;
                recycle_cell(c);
            }
            return;
        }
        CHS_CODE(m_collisions++;);
        prev = c;
        c = c->m_next;
        SASSERT(c);
    }
}

// -----------------------------------
//
// decl_plugin
//
// -----------------------------------

func_decl * decl_plugin::mk_func_decl(decl_kind k, unsigned num_parameters, parameter const * parameters,
                                        unsigned num_args, expr * const * args, sort * range) {
    ptr_buffer<sort> sorts;
    for (unsigned i = 0; i < num_args; i++) {
        sorts.push_back(m_manager->get_sort(args[i]));
    }
    return mk_func_decl(k, num_parameters, parameters, num_args, sorts.c_ptr(), range);
}

// -----------------------------------
//
// basic_decl_plugin (i.e., builtin plugin)
//
// -----------------------------------

basic_decl_plugin::basic_decl_plugin():
    m_bool_sort(0),
    m_true_decl(0),
    m_false_decl(0),
    m_and_decl(0),
    m_or_decl(0),
    m_iff_decl(0),
    m_xor_decl(0),
    m_not_decl(0),
    m_interp_decl(0),
    m_implies_decl(0),
    
    m_proof_sort(0),
    m_undef_decl(0),
    m_true_pr_decl(0),
    m_asserted_decl(0),
    m_goal_decl(0),
    m_modus_ponens_decl(0),
    m_reflexivity_decl(0),
    m_symmetry_decl(0),
    m_transitivity_decl(0),
    m_quant_intro_decl(0),
    m_and_elim_decl(0),
    m_not_or_elim_decl(0),
    m_rewrite_decl(0),
    m_pull_quant_decl(0),
    m_pull_quant_star_decl(0),
    m_push_quant_decl(0),
    m_elim_unused_vars_decl(0),
    m_der_decl(0),
    m_quant_inst_decl(0),

    m_hypothesis_decl(0),
    m_iff_true_decl(0),
    m_iff_false_decl(0),
    m_commutativity_decl(0),
    m_def_axiom_decl(0),
    m_lemma_decl(0),

    m_def_intro_decl(0),
    m_iff_oeq_decl(0),
    m_skolemize_decl(0),
    m_mp_oeq_decl(0),
    m_hyper_res_decl0(0) {
}

bool basic_decl_plugin::check_proof_sorts(basic_op_kind k, unsigned arity, sort * const * domain) const {
    if (k == PR_UNDEF)
        return arity == 0;
    if (arity == 0) 
        return false;
    else {
        for (unsigned i = 0; i < arity - 1; i++) 
            if (domain[i] != m_proof_sort)
                return false;
        return domain[arity-1] == m_bool_sort || domain[arity-1] == m_proof_sort;
    }
}

bool basic_decl_plugin::check_proof_args(basic_op_kind k, unsigned num_args, expr * const * args) const {
    if (k == PR_UNDEF)
        return num_args == 0;
    if (num_args == 0) 
        return false;
    else {
        for (unsigned i = 0; i < num_args - 1; i++) 
            if (m_manager->get_sort(args[i]) != m_proof_sort)
                return false;
        return 
            m_manager->get_sort(args[num_args - 1]) == m_bool_sort || 
            m_manager->get_sort(args[num_args - 1]) == m_proof_sort;
    }
}

func_decl * basic_decl_plugin::mk_bool_op_decl(char const * name, basic_op_kind k, unsigned num_args, bool assoc, bool comm, bool idempotent,
                                               bool flat_associative, bool chainable) {
    ptr_buffer<sort> domain;
    for (unsigned i = 0; i < num_args; i++) 
        domain.push_back(m_bool_sort);
    func_decl_info info(m_family_id, k);
    info.set_associative(assoc);
    info.set_flat_associative(flat_associative);
    info.set_commutative(comm);
    info.set_idempotent(idempotent);
    info.set_chainable(chainable);
    func_decl * d           = m_manager->mk_func_decl(symbol(name), num_args, domain.c_ptr(), m_bool_sort, info);
    m_manager->inc_ref(d);
    return d;
}

func_decl * basic_decl_plugin::mk_implies_decl() {
    sort * domain[2] = { m_bool_sort, m_bool_sort };
    func_decl_info info(m_family_id, OP_IMPLIES);
    info.set_right_associative();
    func_decl * d = m_manager->mk_func_decl(symbol("=>"), 2, domain, m_bool_sort, info);
    m_manager->inc_ref(d);
    return d;
}

func_decl * basic_decl_plugin::mk_proof_decl(
    char const * name, basic_op_kind k, 
    unsigned num_parameters, parameter const* params, unsigned num_parents) {
    ptr_buffer<sort> domain;
    for (unsigned i = 0; i < num_parents; i++) 
        domain.push_back(m_proof_sort);
    domain.push_back(m_bool_sort);
    func_decl_info info(m_family_id, k, num_parameters, params);
    return m_manager->mk_func_decl(symbol(name), num_parents+1, domain.c_ptr(), m_proof_sort, info);
}

func_decl * basic_decl_plugin::mk_proof_decl(char const * name, basic_op_kind k, unsigned num_parents) {
    ptr_buffer<sort> domain;
    for (unsigned i = 0; i < num_parents; i++) 
        domain.push_back(m_proof_sort);
    domain.push_back(m_bool_sort);
    func_decl * d = m_manager->mk_func_decl(symbol(name), num_parents+1, domain.c_ptr(), m_proof_sort, func_decl_info(m_family_id, k));
    m_manager->inc_ref(d);
    return d;
}

func_decl * basic_decl_plugin::mk_compressed_proof_decl(char const * name, basic_op_kind k, unsigned num_parents) {
    ptr_buffer<sort> domain;
    for (unsigned i = 0; i < num_parents; i++) 
        domain.push_back(m_proof_sort);
    func_decl * d = m_manager->mk_func_decl(symbol(name), num_parents, domain.c_ptr(), m_proof_sort, func_decl_info(m_family_id, k));
    m_manager->inc_ref(d);
    return d;
}

func_decl * basic_decl_plugin::mk_proof_decl(char const * name, basic_op_kind k, unsigned num_parents, ptr_vector<func_decl> & cache) {
    if (num_parents >= cache.size()) {
        cache.resize(num_parents+1, 0);
    }
    if (cache[num_parents] == 0) {
        cache[num_parents] = mk_proof_decl(name, k, num_parents);
    }
    return cache[num_parents];
}

func_decl * basic_decl_plugin::mk_proof_decl(basic_op_kind k, unsigned num_parameters, parameter const* params, unsigned num_parents) {
    switch(k) {
    case PR_TH_LEMMA: {
        return mk_proof_decl("th-lemma", k, num_parameters, params, num_parents);
    }
    case PR_QUANT_INST: {
        SASSERT(num_parents == 0);
        return mk_proof_decl("quant-inst", k, num_parameters, params, num_parents);
    }
    case PR_HYPER_RESOLVE: {
        return mk_proof_decl("hyper-res", k, num_parameters, params, num_parents);
    }
    default:
        UNREACHABLE();
        return 0;
    }
}

#define MK_DECL(_decl_,_mk_decl_) if (!_decl_) _decl_ = _mk_decl_; return _decl_;

 
func_decl * basic_decl_plugin::mk_proof_decl(char const* name, basic_op_kind k, unsigned num_parents, func_decl*& fn) {
    if (!fn) {
        fn = mk_proof_decl(name, k, num_parents);
    }
    return fn;
}

func_decl * basic_decl_plugin::mk_proof_decl(basic_op_kind k, unsigned num_parents) {
    SASSERT(k == PR_UNDEF || m_manager->proofs_enabled());
    switch (static_cast<basic_op_kind>(k)) {
        //
        // A description of the semantics of the proof 
        // declarations is provided in z3_api.h
        //
    case PR_UNDEF:                        return m_undef_decl;
    case PR_TRUE:                         return mk_proof_decl("true-axiom", k, 0, m_true_pr_decl);  
    case PR_ASSERTED:                     return mk_proof_decl("asserted", k, 0, m_asserted_decl);
    case PR_GOAL:                         return mk_proof_decl("goal", k, 2, m_goal_decl);
    case PR_MODUS_PONENS:                 return mk_proof_decl("mp", k, 2, m_modus_ponens_decl);
    case PR_REFLEXIVITY:                  return mk_proof_decl("refl", k, 0, m_reflexivity_decl);
    case PR_SYMMETRY:                     return mk_proof_decl("symm", k, 1, m_symmetry_decl);
    case PR_TRANSITIVITY:                 return mk_proof_decl("trans", k, 2, m_transitivity_decl);
    case PR_TRANSITIVITY_STAR:            return mk_proof_decl("trans*", k, num_parents, m_transitivity_star_decls);
    case PR_MONOTONICITY:                 return mk_proof_decl("monotonicity", k, num_parents, m_monotonicity_decls);
    case PR_QUANT_INTRO:                  return mk_proof_decl("quant-intro", k, 1, m_quant_intro_decl);
    case PR_DISTRIBUTIVITY:               return mk_proof_decl("distributivity", k, num_parents, m_distributivity_decls);
    case PR_AND_ELIM:                     return mk_proof_decl("and-elim", k, 1, m_and_elim_decl);
    case PR_NOT_OR_ELIM:                  return mk_proof_decl("not-or-elim", k, 1, m_not_or_elim_decl);
    case PR_REWRITE:                      return mk_proof_decl("rewrite", k, 0, m_rewrite_decl);
    case PR_REWRITE_STAR:                 return mk_proof_decl("rewrite*", k, num_parents, m_rewrite_star_decls);
    case PR_PULL_QUANT:                   return mk_proof_decl("pull-quant", k, 0, m_pull_quant_decl);
    case PR_PULL_QUANT_STAR:              return mk_proof_decl("pull-quant*", k, 0, m_pull_quant_star_decl);
    case PR_PUSH_QUANT:                   return mk_proof_decl("push-quant", k, 0, m_push_quant_decl);
    case PR_ELIM_UNUSED_VARS:             return mk_proof_decl("elim-unused", k, 0, m_elim_unused_vars_decl);
    case PR_DER:                          return mk_proof_decl("der", k, 0, m_der_decl);
    case PR_QUANT_INST:                   return mk_proof_decl("quant-inst", k, 0, m_quant_inst_decl);
    case PR_HYPOTHESIS:                   return mk_proof_decl("hypothesis", k, 0, m_hypothesis_decl);
    case PR_LEMMA:                        return mk_proof_decl("lemma", k, 1, m_lemma_decl);
    case PR_UNIT_RESOLUTION:              return mk_proof_decl("unit-resolution", k, num_parents, m_unit_resolution_decls);
    case PR_IFF_TRUE:                     return mk_proof_decl("iff-true", k, 1, m_iff_true_decl);
    case PR_IFF_FALSE:                    return mk_proof_decl("iff-false", k, 1, m_iff_false_decl);
    case PR_COMMUTATIVITY:                return mk_proof_decl("commutativity", k, 0, m_commutativity_decl);
    case PR_DEF_AXIOM:                    return mk_proof_decl("def-axiom", k, 0, m_def_axiom_decl);
    case PR_DEF_INTRO:                    return mk_proof_decl("intro-def", k, 0, m_def_intro_decl);
    case PR_APPLY_DEF:                    return mk_proof_decl("apply-def", k, num_parents, m_apply_def_decls);
    case PR_IFF_OEQ:                      return mk_proof_decl("iff~", k, 1, m_iff_oeq_decl);
    case PR_NNF_POS:                      return mk_proof_decl("nnf-pos", k, num_parents, m_nnf_pos_decls);
    case PR_NNF_NEG:                      return mk_proof_decl("nnf-neg", k, num_parents, m_nnf_neg_decls);
    case PR_NNF_STAR:                     return mk_proof_decl("nnf*", k, num_parents, m_nnf_star_decls);
    case PR_CNF_STAR:                     return mk_proof_decl("cnf*", k, num_parents, m_cnf_star_decls);
    case PR_SKOLEMIZE:                    return mk_proof_decl("sk", k, 0, m_skolemize_decl);
    case PR_MODUS_PONENS_OEQ:             return mk_proof_decl("mp~", k, 2, m_mp_oeq_decl);
    case PR_TH_LEMMA:                     return mk_proof_decl("th-lemma", k, num_parents, m_th_lemma_decls);
    case PR_HYPER_RESOLVE:                return mk_proof_decl("hyper-res", k, num_parents, m_hyper_res_decl0);
    default:
        UNREACHABLE();
        return 0;
    }
}

void basic_decl_plugin::set_manager(ast_manager * m, family_id id) {
    decl_plugin::set_manager(m, id);

    m_bool_sort = m->mk_sort(symbol("Bool"), sort_info(id, BOOL_SORT, sort_size(2)));
    m->inc_ref(m_bool_sort);

    m_true_decl    = mk_bool_op_decl("true", OP_TRUE);
    m_false_decl   = mk_bool_op_decl("false", OP_FALSE);
    m_and_decl     = mk_bool_op_decl("and", OP_AND, 2, true, true, true, true);
    m_or_decl      = mk_bool_op_decl("or", OP_OR, 2, true, true, true, true);
    m_iff_decl     = mk_bool_op_decl("iff", OP_IFF, 2, false, true, false, false, true);
    m_xor_decl     = mk_bool_op_decl("xor", OP_XOR, 2, true, true);
    m_not_decl     = mk_bool_op_decl("not", OP_NOT, 1);
    m_interp_decl  = mk_bool_op_decl("interp", OP_INTERP, 1);
    m_implies_decl = mk_implies_decl();
    
    m_proof_sort = m->mk_sort(symbol("Proof"), sort_info(id, PROOF_SORT));
    m->inc_ref(m_proof_sort);
    
    m_undef_decl = mk_compressed_proof_decl("undef", PR_UNDEF, 0);    
}

void basic_decl_plugin::get_sort_names(svector<builtin_name> & sort_names, symbol const & logic) {
    if (logic == symbol::null)
        sort_names.push_back(builtin_name("bool", BOOL_SORT));
    sort_names.push_back(builtin_name("Bool", BOOL_SORT));
}

void basic_decl_plugin::get_op_names(svector<builtin_name> & op_names, symbol const & logic) {
    op_names.push_back(builtin_name("true", OP_TRUE));
    op_names.push_back(builtin_name("false", OP_FALSE));   
    op_names.push_back(builtin_name("=", OP_EQ));
    op_names.push_back(builtin_name("distinct", OP_DISTINCT));
    op_names.push_back(builtin_name("ite", OP_ITE));
    op_names.push_back(builtin_name("and", OP_AND));
    op_names.push_back(builtin_name("or", OP_OR));
    op_names.push_back(builtin_name("xor", OP_XOR));
    op_names.push_back(builtin_name("not", OP_NOT));
    op_names.push_back(builtin_name("interp", OP_INTERP));
    op_names.push_back(builtin_name("=>", OP_IMPLIES));
    if (logic == symbol::null) {
        // user friendly aliases
        op_names.push_back(builtin_name("implies", OP_IMPLIES));
        op_names.push_back(builtin_name("iff", OP_IFF));
        op_names.push_back(builtin_name("if_then_else", OP_ITE));
        op_names.push_back(builtin_name("if", OP_ITE));
        op_names.push_back(builtin_name("&&", OP_AND));
        op_names.push_back(builtin_name("||", OP_OR));
        op_names.push_back(builtin_name("equals", OP_EQ));
        op_names.push_back(builtin_name("equiv", OP_IFF));
        op_names.push_back(builtin_name("@@", OP_INTERP));
    }
}

bool basic_decl_plugin::is_value(app* a) const {
    return a->get_decl() == m_true_decl || a->get_decl() == m_false_decl;
}

bool basic_decl_plugin::is_unique_value(app* a) const {
    return is_value(a);
}

void basic_decl_plugin::finalize() {
#define DEC_REF(FIELD) if (FIELD) { m_manager->dec_ref(FIELD); }
#define DEC_ARRAY_REF(FIELD) m_manager->dec_array_ref(FIELD.size(), FIELD.begin())
    DEC_REF(m_bool_sort);
    DEC_REF(m_true_decl);
    DEC_REF(m_false_decl);
    DEC_REF(m_and_decl);
    DEC_REF(m_or_decl);
    DEC_REF(m_not_decl);
    DEC_REF(m_interp_decl);
    DEC_REF(m_iff_decl);
    DEC_REF(m_xor_decl);
    DEC_REF(m_implies_decl);
    DEC_ARRAY_REF(m_eq_decls);
    DEC_ARRAY_REF(m_ite_decls);
    
    DEC_ARRAY_REF(m_oeq_decls);
    DEC_REF(m_proof_sort);
    DEC_REF(m_undef_decl);
    DEC_REF(m_true_pr_decl);
    DEC_REF(m_asserted_decl);
    DEC_REF(m_goal_decl);
    DEC_REF(m_modus_ponens_decl);
    DEC_REF(m_reflexivity_decl);
    DEC_REF(m_symmetry_decl);
    DEC_REF(m_transitivity_decl);
    DEC_REF(m_quant_intro_decl);
    DEC_REF(m_and_elim_decl);
    DEC_REF(m_not_or_elim_decl);
    DEC_REF(m_rewrite_decl);
    DEC_REF(m_pull_quant_decl);
    DEC_REF(m_pull_quant_star_decl);
    DEC_REF(m_push_quant_decl);
    DEC_REF(m_elim_unused_vars_decl);
    DEC_REF(m_der_decl);
    DEC_REF(m_quant_inst_decl);
    DEC_ARRAY_REF(m_monotonicity_decls);
    DEC_ARRAY_REF(m_transitivity_star_decls);
    DEC_ARRAY_REF(m_distributivity_decls);
    DEC_ARRAY_REF(m_assoc_flat_decls);
    DEC_ARRAY_REF(m_rewrite_star_decls);

    DEC_REF(m_hypothesis_decl);
    DEC_REF(m_iff_true_decl);
    DEC_REF(m_iff_false_decl);
    DEC_REF(m_commutativity_decl);
    DEC_REF(m_def_axiom_decl);
    DEC_REF(m_lemma_decl);
    DEC_ARRAY_REF(m_unit_resolution_decls);

    DEC_REF(m_def_intro_decl);
    DEC_REF(m_iff_oeq_decl);
    DEC_REF(m_skolemize_decl);
    DEC_REF(m_mp_oeq_decl);
    DEC_ARRAY_REF(m_apply_def_decls);
    DEC_ARRAY_REF(m_nnf_pos_decls);
    DEC_ARRAY_REF(m_nnf_neg_decls);
    DEC_ARRAY_REF(m_nnf_star_decls);
    DEC_ARRAY_REF(m_cnf_star_decls);

    DEC_ARRAY_REF(m_th_lemma_decls);
    DEC_REF(m_hyper_res_decl0);

}

sort * basic_decl_plugin::mk_sort(decl_kind k, unsigned num_parameters, parameter const * parameters) {
    if (k == BOOL_SORT)
        return m_bool_sort;
    SASSERT(k == PROOF_SORT);
    return m_proof_sort;
}

func_decl * basic_decl_plugin::mk_eq_decl_core(char const * name, decl_kind k, sort * s, ptr_vector<func_decl> & cache) {
    unsigned id = s->get_decl_id();
    force_ptr_array_size(cache, id + 1);
    if (cache[id] == 0) {
        sort * domain[2] = { s, s};
        func_decl_info info(m_family_id, k);
        info.set_commutative();
        info.set_chainable();
        func_decl * decl = m_manager->mk_func_decl(symbol(name), 2, domain, m_bool_sort, info);
        SASSERT(decl->is_chainable());
        cache[id] = decl;
        m_manager->inc_ref(decl);
    }
    return cache[id];
}

func_decl * basic_decl_plugin::mk_ite_decl(sort * s) {
    unsigned id = s->get_decl_id();
    force_ptr_array_size(m_ite_decls, id + 1);
    if (m_ite_decls[id] == 0) {
        sort * domain[3] = { m_bool_sort, s, s};
        func_decl * decl = m_manager->mk_func_decl(symbol("if"), 3, domain, s, func_decl_info(m_family_id, OP_ITE));
        m_ite_decls[id] = decl;
        m_manager->inc_ref(decl);
    }
    return m_ite_decls[id];
}

sort* basic_decl_plugin::join(unsigned n, sort* const* srts) {
    SASSERT(n > 0);
    sort* s = srts[0];
    while (n > 1) {
        ++srts;
        --n;
        s = join(s, *srts);
    }
    return s;
}

sort* basic_decl_plugin::join(unsigned n, expr* const* es) {
    SASSERT(n > 0);
    sort* s = m_manager->get_sort(*es);
    while (n > 1) {
        ++es;
        --n;
        s = join(s, m_manager->get_sort(*es));
    }
    return s;
}

sort* basic_decl_plugin::join(sort* s1, sort* s2) {
    if (s1 == s2) return s1;
    if (s1->get_family_id() == m_manager->m_arith_family_id &&
        s2->get_family_id() == m_manager->m_arith_family_id) {
        if (s1->get_decl_kind() == REAL_SORT) {
            return s1;
        }
        return s2;
    }
    std::ostringstream buffer;
    buffer << "Sorts " << mk_pp(s1, *m_manager) << " and " << mk_pp(s2, *m_manager) << " are incompatible";
    throw ast_exception(buffer.str().c_str());
}


func_decl * basic_decl_plugin::mk_func_decl(decl_kind k, unsigned num_parameters, parameter const * parameters,
                                          unsigned arity, sort * const * domain, sort * range) {
    switch (static_cast<basic_op_kind>(k)) {
    case OP_TRUE:    return m_true_decl;
    case OP_FALSE:   return m_false_decl;
    case OP_AND:     return m_and_decl;
    case OP_OR:      return m_or_decl;
    case OP_NOT:     return m_not_decl;
    case OP_INTERP:  return m_interp_decl;
    case OP_IFF:     return m_iff_decl;
    case OP_IMPLIES: return m_implies_decl;
    case OP_XOR:     return m_xor_decl;
    case OP_ITE:     return arity == 3 ? mk_ite_decl(join(domain[1], domain[2])) : 0;
        // eq and oeq must have at least two arguments, they can have more since they are chainable
    case OP_EQ:      return arity >= 2 ? mk_eq_decl_core("=", OP_EQ, join(arity, domain), m_eq_decls) : 0;
    case OP_OEQ:     return arity >= 2 ? mk_eq_decl_core("~", OP_OEQ, join(arity, domain), m_oeq_decls) : 0;
    case OP_DISTINCT: {
        func_decl_info info(m_family_id, OP_DISTINCT);
        info.set_pairwise();
        for (unsigned i = 1; i < arity; i++) {        
            if (domain[i] != domain[0]) {
                std::ostringstream buffer;
                buffer << "Sort mismatch between first argument and argument " << (i+1);
                throw ast_exception(buffer.str().c_str());
            }
        }
        return m_manager->mk_func_decl(symbol("distinct"), arity, domain, m_bool_sort, info);
    }
    default:
        break;
    }

    SASSERT(is_proof(k));
    
    if (!check_proof_sorts(static_cast<basic_op_kind>(k), arity, domain))
        m_manager->raise_exception("Invalid proof object.");

    if (num_parameters == 0) {
        return mk_proof_decl(static_cast<basic_op_kind>(k), arity - 1);
    }
    return mk_proof_decl(static_cast<basic_op_kind>(k), num_parameters, parameters, arity - 1);
}

func_decl * basic_decl_plugin::mk_func_decl(decl_kind k, unsigned num_parameters, parameter const * parameters,
                                            unsigned num_args, expr * const * args, sort * range) {
    switch (static_cast<basic_op_kind>(k)) {
    case OP_TRUE:    return m_true_decl;
    case OP_FALSE:   return m_false_decl;
    case OP_AND:     return m_and_decl;
    case OP_OR:      return m_or_decl;
    case OP_NOT:     return m_not_decl;
    case OP_INTERP:  return m_interp_decl;
    case OP_IFF:     return m_iff_decl;
    case OP_IMPLIES: return m_implies_decl;
    case OP_XOR:     return m_xor_decl;
    case OP_ITE:     return num_args == 3 ? mk_ite_decl(join(m_manager->get_sort(args[1]), m_manager->get_sort(args[2]))): 0;
        // eq and oeq must have at least two arguments, they can have more since they are chainable
    case OP_EQ:      return num_args >= 2 ? mk_eq_decl_core("=", OP_EQ, join(num_args, args), m_eq_decls) : 0;
    case OP_OEQ:     return num_args >= 2 ? mk_eq_decl_core("~", OP_OEQ, join(num_args, args), m_oeq_decls) : 0;
    case OP_DISTINCT:
        return decl_plugin::mk_func_decl(k, num_parameters, parameters, num_args, args, range);
    default:
        break;
    }

    SASSERT(is_proof(k));

    if (!check_proof_args(static_cast<basic_op_kind>(k), num_args, args)) 
        m_manager->raise_exception("Invalid proof object.");

    if (num_parameters == 0) {
        return mk_proof_decl(static_cast<basic_op_kind>(k), num_args - 1);
    }
    return mk_proof_decl(static_cast<basic_op_kind>(k), num_parameters, parameters, num_args - 1);
}

expr * basic_decl_plugin::get_some_value(sort * s) {
    if (s == m_bool_sort)
        return m_manager->mk_false();
    return 0;
}

bool basic_recognizers::is_ite(expr const * n, expr * & t1, expr * & t2, expr * & t3) const { 
    if (is_ite(n)) { 
        t1 = to_app(n)->get_arg(0); 
        t2 = to_app(n)->get_arg(1); 
        t3 = to_app(n)->get_arg(2);
        return true; 
    } 
    return false; 
}

// -----------------------------------
//
// label_decl_plugin 
//
// -----------------------------------

label_decl_plugin::label_decl_plugin():
    m_lblpos("lblpos"),
    m_lblneg("lblneg"),
    m_lbllit("lbl-lit") {
}

label_decl_plugin::~label_decl_plugin() {
}

void label_decl_plugin::set_manager(ast_manager * m, family_id id) {
    decl_plugin::set_manager(m, id);
}

sort * label_decl_plugin::mk_sort(decl_kind k, unsigned num_parameters, parameter const * parameters) {
    UNREACHABLE();
    return 0;
}

func_decl * label_decl_plugin::mk_func_decl(decl_kind k, unsigned num_parameters, parameter const * parameters, 
                                          unsigned arity, sort * const * domain, sort * range) {
    if (k == OP_LABEL) {
        if (arity != 1 || num_parameters < 2 || !parameters[0].is_int() || !parameters[1].is_symbol() || !m_manager->is_bool(domain[0])) {
            m_manager->raise_exception("invalid label declaration");
            return 0;
        }
        for (unsigned i = 2; i < num_parameters; i++) {
            if (!parameters[i].is_symbol()) {
                m_manager->raise_exception("invalid label declaration");
                return 0;
            }
        }
        return m_manager->mk_func_decl(parameters[0].get_int() ? m_lblpos : m_lblneg, arity, domain, domain[0], 
                                       func_decl_info(m_family_id, OP_LABEL, num_parameters, parameters));
    }
    else {
        SASSERT(k == OP_LABEL_LIT);
        if (arity != 0) {
            m_manager->raise_exception("invalid label literal declaration");
            return 0;
        }
        for (unsigned i = 0; i < num_parameters; i++) {
            if (!parameters[i].is_symbol()) {
                m_manager->raise_exception("invalid label literal declaration");
                return 0;
            }
        }
        return m_manager->mk_func_decl(m_lbllit, 0, static_cast<sort * const *>(0), m_manager->mk_bool_sort(),
                                       func_decl_info(m_family_id, OP_LABEL_LIT, num_parameters, parameters));
    }
}

// -----------------------------------
//
// pattern_decl_plugin 
//
// -----------------------------------

sort * pattern_decl_plugin::mk_sort(decl_kind k, unsigned num_parameters, parameter const * parameters) {
    UNREACHABLE();
    return 0;
}

func_decl * pattern_decl_plugin::mk_func_decl(decl_kind k, unsigned num_parameters, parameter const * parameters, 
                                            unsigned arity, sort * const * domain, sort * range) {
    return m_manager->mk_func_decl(symbol("pattern"), arity, domain, 
                                   m_manager->mk_bool_sort(), // the range can be an arbitrary sort.
                                   func_decl_info(m_family_id, OP_PATTERN));
}

// -----------------------------------
//
// model_value_decl_plugin 
//
// -----------------------------------

sort * model_value_decl_plugin::mk_sort(decl_kind k, unsigned num_parameters, parameter const * parameters) {
    UNREACHABLE();
    return 0;
}

func_decl * model_value_decl_plugin::mk_func_decl(decl_kind k, unsigned num_parameters, parameter const * parameters, 
                                                  unsigned arity, sort * const * domain, sort * range) {
    SASSERT(k == OP_MODEL_VALUE);
    if (arity != 0 || num_parameters != 2 || !parameters[0].is_int() || !parameters[1].is_ast() || !is_sort(parameters[1].get_ast())) {
        UNREACHABLE();
        m_manager->raise_exception("invalid model value");
        return 0;
    }
    int idx  = parameters[0].get_int();
    sort * s = to_sort(parameters[1].get_ast());
    string_buffer<64> buffer;
    buffer << s->get_name().bare_str() << "!val!" << idx;
    func_decl_info info(m_family_id, k, num_parameters, parameters);
    info.m_private_parameters = true;
    return m_manager->mk_func_decl(symbol(buffer.c_str()), 0, static_cast<sort * const *>(0), s, info);
}

bool model_value_decl_plugin::is_value(app* n) const {
    return is_app_of(n, m_family_id, OP_MODEL_VALUE);
}

bool model_value_decl_plugin::is_unique_value(app* n) const {
    return is_value(n);
}

// -----------------------------------
//
// user_sort_plugin
//
// -----------------------------------

sort * user_sort_plugin::mk_sort(decl_kind k, unsigned num_parameters, parameter const * parameters) {
    SASSERT(m_family_id != null_family_id);
    SASSERT(k < static_cast<int>(m_sort_names.size()));
    sort_info si(m_family_id, k, num_parameters, parameters);
    return m_manager->mk_sort(m_sort_names[k], si);
}

func_decl * user_sort_plugin::mk_func_decl(decl_kind k, unsigned num_parameters, parameter const * parameters, 
                                           unsigned arity, sort * const * domain, sort * range) {
    UNREACHABLE();
    return 0;
}

decl_kind user_sort_plugin::register_name(symbol s) {
    decl_kind k;
    if (m_name2decl_kind.find(s, k))
        return k;
    k = m_sort_names.size();
    m_sort_names.push_back(s);
    m_name2decl_kind.insert(s, k);
    return k;
}

decl_plugin * user_sort_plugin::mk_fresh() {
    user_sort_plugin * p = alloc(user_sort_plugin);
    svector<symbol>::iterator it  = m_sort_names.begin();
    svector<symbol>::iterator end = m_sort_names.end();
    for (; it != end; ++it) 
        p->register_name(*it);
    return p;
}


// -----------------------------------
//
// ast_manager
//
// -----------------------------------

ast_manager::ast_manager(proof_gen_mode m, char const * trace_file, bool is_format_manager):
    m_alloc("ast_manager"),
    m_expr_array_manager(*this, m_alloc),
    m_expr_dependency_manager(*this, m_alloc),
    m_expr_dependency_array_manager(*this, m_alloc),
    m_proof_mode(m),
    m_trace_stream(0),
    m_trace_stream_owner(false) {

    if (trace_file) {
        m_trace_stream       = alloc(std::fstream, trace_file, std::ios_base::out);
        m_trace_stream_owner = true;
    }

    if (!is_format_manager)
        m_format_manager = alloc(ast_manager, PGM_DISABLED, m_trace_stream, true);
    else 
        m_format_manager = 0;
    init();
}

ast_manager::ast_manager(proof_gen_mode m, std::fstream * trace_stream, bool is_format_manager):
    m_alloc("ast_manager"),
    m_expr_array_manager(*this, m_alloc),
    m_expr_dependency_manager(*this, m_alloc),
    m_expr_dependency_array_manager(*this, m_alloc),
    m_proof_mode(m),
    m_trace_stream(trace_stream),
    m_trace_stream_owner(false) {

    if (!is_format_manager)
        m_format_manager = alloc(ast_manager, PGM_DISABLED, trace_stream, true);
    else 
        m_format_manager = 0;
    init();
}

ast_manager::ast_manager(ast_manager const & src, bool disable_proofs):
    m_alloc("ast_manager"),
    m_expr_array_manager(*this, m_alloc),
    m_expr_dependency_manager(*this, m_alloc),
    m_expr_dependency_array_manager(*this, m_alloc),
    m_proof_mode(disable_proofs ? PGM_DISABLED : src.m_proof_mode),
    m_trace_stream(src.m_trace_stream),
    m_trace_stream_owner(false) {
    SASSERT(!src.is_format_manager());
    m_format_manager = alloc(ast_manager, PGM_DISABLED, m_trace_stream, true);
    init();
    copy_families_plugins(src);
}

void ast_manager::init() {
    m_int_real_coercions = true;
    m_debug_ref_count = false;
    m_fresh_id = 0;
    m_expr_id_gen.reset(0);
    m_decl_id_gen.reset(c_first_decl_id);
    m_some_value_proc = 0;
    m_basic_family_id          = mk_family_id("basic");
    m_label_family_id          = mk_family_id("label");
    m_pattern_family_id        = mk_family_id("pattern");
    m_model_value_family_id    = mk_family_id("model-value");
    m_user_sort_family_id      = mk_family_id("user-sort");
    m_arith_family_id          = mk_family_id("arith");
    basic_decl_plugin * plugin = alloc(basic_decl_plugin);
    register_plugin(m_basic_family_id, plugin);
    m_bool_sort = plugin->mk_bool_sort();
    inc_ref(m_bool_sort);
    m_proof_sort = plugin->mk_proof_sort();
    inc_ref(m_proof_sort);
    m_undef_proof = mk_const(m_basic_family_id, PR_UNDEF);
    inc_ref(m_undef_proof);
    register_plugin(m_label_family_id, alloc(label_decl_plugin));
    register_plugin(m_pattern_family_id, alloc(pattern_decl_plugin));
    register_plugin(m_model_value_family_id, alloc(model_value_decl_plugin));
    register_plugin(m_user_sort_family_id, alloc(user_sort_plugin));
    m_true  = mk_const(m_basic_family_id, OP_TRUE);
    inc_ref(m_true);
    m_false = mk_const(m_basic_family_id, OP_FALSE);
    inc_ref(m_false);
}

ast_manager::~ast_manager() {
    SASSERT(is_format_manager() || !m_family_manager.has_family(symbol("format")));

    dec_ref(m_bool_sort);
    dec_ref(m_proof_sort);
    dec_ref(m_true);
    dec_ref(m_false);
    dec_ref(m_undef_proof);
    ptr_vector<decl_plugin>::iterator it  = m_plugins.begin();
    ptr_vector<decl_plugin>::iterator end = m_plugins.end();
    for (; it != end; ++it) {
        if (*it)
            (*it)->finalize();
    }
    it = m_plugins.begin();
    for (; it != end; ++it) {
        if (*it)
            dealloc(*it);
    }
    DEBUG_CODE({
        if (!m_ast_table.empty()) 
            std::cout << "ast_manager LEAKED: " << m_ast_table.size() << std::endl;
    });
#if 1
    DEBUG_CODE({
        ast_table::iterator it_a = m_ast_table.begin();
        ast_table::iterator end_a = m_ast_table.end();
        for (; it_a != end_a; ++it_a) {
            ast* a = (*it_a);
            std::cout << "Leaked: ";
            if (is_sort(a)) {
                std::cout << to_sort(a)->get_name() << "\n";
            }
            else {
                std::cout << mk_ll_pp(a, *this, false);
            }
        }
    });
#endif
    if (m_format_manager != 0)
        dealloc(m_format_manager);
    if (m_trace_stream_owner) {
        std::fstream & tmp = * m_trace_stream;
        tmp << "[eof]\n";
        tmp.close();
        dealloc(m_trace_stream);
        m_trace_stream = 0;
    }
}

void ast_manager::set_cancel(bool f) {
    for (unsigned i = 0; i < m_plugins.size(); i++) {
        m_plugins[i]->set_cancel(f);
    }
}

void ast_manager::compact_memory() {
    m_alloc.consolidate();
    unsigned capacity = m_ast_table.capacity();
    if (capacity > 4*m_ast_table.size()) {
        ast_table new_ast_table;           
        ast_table::iterator it  = m_ast_table.begin();
        ast_table::iterator end = m_ast_table.end();
        for (; it != end; ++it) {
            new_ast_table.insert(*it);
        }
        m_ast_table.swap(new_ast_table);
        IF_VERBOSE(10, verbose_stream() << "(ast-table :prev-capacity " << capacity 
                   << " :capacity " << m_ast_table.capacity() << " :size " << m_ast_table.size() << ")\n";);
    }
    else {
        IF_VERBOSE(10, verbose_stream() << "(ast-table :capacity " << m_ast_table.capacity() << " :size " << m_ast_table.size() << ")\n";);
    }
}

void ast_manager::compress_ids() {
    ptr_vector<ast> asts;
    m_expr_id_gen.cleanup();
    m_decl_id_gen.cleanup(c_first_decl_id);
    ast_table::iterator it  = m_ast_table.begin();
    ast_table::iterator end = m_ast_table.end();
    for (; it != end; ++it) {
        ast * n = *it;
        if (is_decl(n))
            n->m_id = m_decl_id_gen.mk();
        else
            n->m_id = m_expr_id_gen.mk();
        asts.push_back(n);
    }
    m_ast_table.finalize();
    ptr_vector<ast>::iterator it2  = asts.begin();
    ptr_vector<ast>::iterator end2 = asts.end();
    for (; it2 != end2; ++it2)
        m_ast_table.insert(*it2);
}

void ast_manager::raise_exception(char const * msg) {
    throw ast_exception(msg);
}

void ast_manager::copy_families_plugins(ast_manager const & from) {
    TRACE("copy_families_plugins",
          tout << "target:\n";
          for (family_id fid = 0; m_family_manager.has_family(fid); fid++) {
              tout << "fid: " << fid << " fidname: " << get_family_name(fid) << "\n";
          });
    for (family_id fid = 0; from.m_family_manager.has_family(fid); fid++) {
      SASSERT(from.is_builtin_family_id(fid) == is_builtin_family_id(fid));
      SASSERT(!from.is_builtin_family_id(fid) || m_family_manager.has_family(fid));
      symbol fid_name   = from.get_family_name(fid);
      TRACE("copy_families_plugins", tout << "copying: " << fid_name << ", src fid: " << fid 
            << ", target has_family: " << m_family_manager.has_family(fid) << "\n";
            if (m_family_manager.has_family(fid)) tout << get_family_id(fid_name) << "\n";);
      if (!m_family_manager.has_family(fid)) {
          family_id new_fid = mk_family_id(fid_name);          
          TRACE("copy_families_plugins", tout << "new target fid created: " << new_fid << " fid_name: " << fid_name << "\n";);
      }
      TRACE("copy_families_plugins", tout << "target fid: " << get_family_id(fid_name) << "\n";);
      SASSERT(fid == get_family_id(fid_name));
      if (from.has_plugin(fid) && !has_plugin(fid)) {
          decl_plugin * new_p = from.get_plugin(fid)->mk_fresh();            
          register_plugin(fid, new_p);
          SASSERT(new_p->get_family_id() == fid);
          SASSERT(has_plugin(fid));
      }
      SASSERT(from.m_family_manager.has_family(fid) == m_family_manager.has_family(fid));
      SASSERT(from.get_family_id(fid_name) == get_family_id(fid_name));
      SASSERT(!from.has_plugin(fid) || has_plugin(fid));      
    }
}

void ast_manager::set_next_expr_id(unsigned id) {
    while (true) {
        id = m_expr_id_gen.set_next_id(id);
        ast_table::iterator it  = m_ast_table.begin();
        ast_table::iterator end = m_ast_table.end();
        for (; it != end; ++it) {
            ast * curr = *it;
            if (curr->get_id() == id)
                break;
        }
        if (it == end)
            return;
        // id is in use, move to the next one.
        id++; 
    }
}

unsigned ast_manager::get_node_size(ast const * n) { return ::get_node_size(n); }

void ast_manager::register_plugin(symbol const & s, decl_plugin * plugin) {
    family_id id = m_family_manager.mk_family_id(s);
    SASSERT(is_format_manager() || s != symbol("format"));
    register_plugin(id, plugin);
}

decl_plugin * ast_manager::get_plugin(family_id fid) const {
    return m_plugins.get(fid, 0);
}


bool ast_manager::is_value(expr* e) const {
    decl_plugin const * p = 0;
    if (is_app(e)) {
        p = get_plugin(to_app(e)->get_family_id());
        return p && p->is_value(to_app(e));
    }
    return false;
}

bool ast_manager::is_unique_value(expr* e) const {
    decl_plugin const * p = 0;
    if (is_app(e)) {
        p = get_plugin(to_app(e)->get_family_id());
        return p && p->is_unique_value(to_app(e));
    }
    return false;
}

bool ast_manager::are_equal(expr * a, expr * b) const {
    if (is_app(a) && is_app(b)) {
        app* ap = to_app(a), *bp = to_app(b);
        decl_plugin const * p = get_plugin(ap->get_family_id());
        if (!p) {
            p = get_plugin(bp->get_family_id());
        }
        return p && p->are_equal(ap, bp);
    }
    return false;
}

bool ast_manager::are_distinct(expr* a, expr* b) const {
    if (is_app(a) && is_app(b)) {
        app* ap = to_app(a), *bp = to_app(b);
        decl_plugin const * p = get_plugin(ap->get_family_id());
        if (!p) {
            p = get_plugin(bp->get_family_id());
        }
        return p && p->are_distinct(ap, bp);
    }
    return false;
}

void ast_manager::register_plugin(family_id id, decl_plugin * plugin) {
    SASSERT(m_plugins.get(id, 0) == 0);
    m_plugins.setx(id, plugin, 0);
    plugin->set_manager(this, id);
}

bool ast_manager::is_bool(expr const * n) const {
    return get_sort(n) == m_bool_sort;
}

#ifdef Z3DEBUG
bool ast_manager::slow_not_contains(ast const * n) {
    ast_table::iterator it  = m_ast_table.begin();
    ast_table::iterator end = m_ast_table.end();
    unsigned num = 0;
    for (; it != end; ++it) {
        ast * curr = *it;
        if (compare_nodes(curr, n)) {
            TRACE("nondet_bug", 
                  tout << "id1:   " << curr->get_id() << ", id2: " << n->get_id() << "\n";
                  tout << "hash1: " << get_node_hash(curr) << ", hash2: " << get_node_hash(n) << "\n";);
            return false;
        }
        SASSERT(!(is_app(n) && is_app(curr) &&
                  to_app(n)->get_decl() == to_app(curr)->get_decl() &&
                  to_app(n)->get_num_args() == 0 &&
                  to_app(curr)->get_num_args() == 0));
        num++;
    }
    SASSERT(num == m_ast_table.size());
    return true;
}
#endif

ast * ast_manager::register_node_core(ast * n) {
    unsigned h = get_node_hash(n); 
    n->m_hash = h;
#ifdef Z3DEBUG
    bool contains = m_ast_table.contains(n);
    CASSERT("nondet_bug", contains || slow_not_contains(n));
#endif

#if 0
    static unsigned counter = 0;
    counter++;
    if (counter % 100000 == 0)
        verbose_stream() << "[ast-table] counter: " << counter << " collisions: " << m_ast_table.collisions() << " capacity: " << m_ast_table.capacity() << " size: " << m_ast_table.size() << "\n";
#endif

    ast * r = m_ast_table.insert_if_not_there(n);
    SASSERT(r->m_hash == h);
    if (r != n) {
#if 0
        static unsigned reused = 0;
        reused++;
        if (reused % 100000 == 0)
            verbose_stream() << "[ast-table] reused: " << reused << "\n";
#endif
        SASSERT(contains);
        SASSERT(m_ast_table.contains(n));
        if (is_func_decl(r) && to_func_decl(r)->get_range() != to_func_decl(n)->get_range()) {
            std::ostringstream buffer;
            buffer << "Recycling of declaration for the same name '" << to_func_decl(r)->get_name().str().c_str() << "'"
                   << " and domain, but different range type is not permitted";
            throw ast_exception(buffer.str().c_str());
        }
        deallocate_node(n, ::get_node_size(n));
        return r;
    }
    else {
        SASSERT(!contains);
        SASSERT(m_ast_table.contains(n));
    }

    n->m_id   = is_decl(n) ? m_decl_id_gen.mk() : m_expr_id_gen.mk();

    TRACE("ast", tout << "Object " << n->m_id << " was created.\n";);
    TRACE("mk_var_bug", tout << "mk_ast: " << n->m_id << "\n";);
    // increment reference counters
    switch (n->get_kind()) {
    case AST_SORT:
        if (to_sort(n)->m_info != 0) {
            to_sort(n)->m_info = alloc(sort_info, *(to_sort(n)->get_info()));
            to_sort(n)->m_info->init_eh(*this);
        }
        break;
    case AST_FUNC_DECL:
        if (to_func_decl(n)->m_info != 0) {
            to_func_decl(n)->m_info = alloc(func_decl_info, *(to_func_decl(n)->get_info()));
            to_func_decl(n)->m_info->init_eh(*this);
        }
        inc_array_ref(to_func_decl(n)->get_arity(), to_func_decl(n)->get_domain());
        inc_ref(to_func_decl(n)->get_range());
        break;
    case AST_APP: {
        app * t = to_app(n);
        inc_ref(t->get_decl());
        unsigned num_args = t->get_num_args();
        if (num_args > 0) {
            app_flags * f     = t->flags();
            *f = mk_default_app_flags();
            SASSERT(t->is_ground());
            SASSERT(!t->has_quantifiers());
            SASSERT(!t->has_labels());
            if (is_label(t))
                f->m_has_labels = true;
            unsigned depth = 0;
            for (unsigned i = 0; i < num_args; i++) {
                expr * arg = t->get_arg(i);
                inc_ref(arg);
                unsigned arg_depth = 0;
                switch (arg->get_kind()) {
                case AST_APP: {
                    app_flags * arg_flags = to_app(arg)->flags();
                    arg_depth = arg_flags->m_depth;
                    if (arg_flags->m_has_quantifiers)
                        f->m_has_quantifiers = true;
                    if (arg_flags->m_has_labels)
                        f->m_has_labels = true;
                    if (!arg_flags->m_ground)
                        f->m_ground = false;
                    break;
                }
                case AST_QUANTIFIER:
                    f->m_has_quantifiers = true;
                    f->m_ground          = false;
                    arg_depth            = to_quantifier(arg)->get_depth();
                    break;
                case AST_VAR:
                    f->m_ground          = false;
                    arg_depth            = 1;
                    break;
                default:
                    UNREACHABLE();
                }
                if (arg_depth > depth) 
                    depth = arg_depth;
            }
            depth++;
            if (depth > c_max_depth)
                depth = c_max_depth;
            f->m_depth = depth;
            SASSERT(t->get_depth() == depth);
        }
        break;
    }
    case AST_VAR:
        inc_ref(to_var(n)->get_sort());
        break;
    case AST_QUANTIFIER:
        inc_array_ref(to_quantifier(n)->get_num_decls(), to_quantifier(n)->get_decl_sorts());
        inc_ref(to_quantifier(n)->get_expr());
        inc_array_ref(to_quantifier(n)->get_num_patterns(), to_quantifier(n)->get_patterns());
        inc_array_ref(to_quantifier(n)->get_num_no_patterns(), to_quantifier(n)->get_no_patterns());
        break;
    default:
        break;
    }
    return n;
}

void ast_manager::delete_node(ast * n) {
    TRACE("delete_node_bug", tout << mk_ll_pp(n, *this) << "\n";);
    ptr_buffer<ast> worklist;
    worklist.push_back(n);

    while (!worklist.empty()) {
        n = worklist.back();
        worklist.pop_back();
        
        TRACE("ast", tout << "Deleting object " << n->m_id << " " << n << "\n";);
        CTRACE("del_quantifier", is_quantifier(n), tout << "deleting quantifier " << n->m_id << " " << n << "\n";);
        TRACE("mk_var_bug", tout << "del_ast: " << n->m_id << "\n";);
        TRACE("ast_delete_node", tout << mk_bounded_pp(n, *this) << "\n";);

        SASSERT(m_ast_table.contains(n));
        m_ast_table.erase(n);
        SASSERT(!m_ast_table.contains(n));
        SASSERT(!m_debug_ref_count || !m_debug_free_indices.contains(n->m_id));

#ifdef RECYCLE_FREE_AST_INDICES
        if (!m_debug_ref_count) {
            if (is_decl(n))
                m_decl_id_gen.recycle(n->m_id);
            else 
                m_expr_id_gen.recycle(n->m_id);
        }
#endif
        switch (n->get_kind()) {
        case AST_SORT:
            if (to_sort(n)->m_info != 0 && !m_debug_ref_count) { 
                sort_info * info = to_sort(n)->get_info();
                info->del_eh(*this);
                dealloc(info); 
            }
            break;
        case AST_FUNC_DECL:
            if (to_func_decl(n)->m_info != 0 && !m_debug_ref_count) { 
                func_decl_info * info = to_func_decl(n)->get_info();
                info->del_eh(*this);
                dealloc(info);
            }
            dec_array_ref(worklist, to_func_decl(n)->get_arity(), to_func_decl(n)->get_domain());
            dec_ref(worklist, to_func_decl(n)->get_range());
            break;
        case AST_APP:
            dec_ref(worklist, to_app(n)->get_decl());
            dec_array_ref(worklist, to_app(n)->get_num_args(), to_app(n)->get_args());
            break;
        case AST_VAR:
            dec_ref(worklist, to_var(n)->get_sort());
            break;
        case AST_QUANTIFIER:
            dec_array_ref(worklist, to_quantifier(n)->get_num_decls(), to_quantifier(n)->get_decl_sorts());
            dec_ref(worklist, to_quantifier(n)->get_expr());
            dec_array_ref(worklist, to_quantifier(n)->get_num_patterns(), to_quantifier(n)->get_patterns());
            dec_array_ref(worklist, to_quantifier(n)->get_num_no_patterns(), to_quantifier(n)->get_no_patterns());
            break;
    default:
        break;
        }
        if (m_debug_ref_count) {
            m_debug_free_indices.insert(n->m_id,0);
        }
        deallocate_node(n, ::get_node_size(n));
    }
}

sort * ast_manager::mk_sort(family_id fid, decl_kind k, unsigned num_parameters, parameter const * parameters) {
    decl_plugin * p = get_plugin(fid);
    if (p)
        return p->mk_sort(k, num_parameters, parameters);
    return 0;
}
    
func_decl * ast_manager::mk_func_decl(family_id fid, decl_kind k, unsigned num_parameters, parameter const * parameters,
                                      unsigned arity, sort * const * domain, sort * range) {
    decl_plugin * p = get_plugin(fid);
    if (p)
        return p->mk_func_decl(k, num_parameters, parameters, arity, domain, range);
    return 0;
}

func_decl * ast_manager::mk_func_decl(family_id fid, decl_kind k, unsigned num_parameters, parameter const * parameters, 
                                      unsigned num_args, expr * const * args, sort * range) {
    decl_plugin * p = get_plugin(fid);
    if (p)
        return p->mk_func_decl(k, num_parameters, parameters, num_args, args, range);
    return 0;
} 

app * ast_manager::mk_app(family_id fid, decl_kind k, unsigned num_parameters, parameter const * parameters,
                          unsigned num_args, expr * const * args, sort * range) {
    func_decl * decl = mk_func_decl(fid, k, num_parameters, parameters, num_args, args, range);
    if (decl != 0)
        return mk_app(decl, num_args, args);
    return 0;
}

app * ast_manager::mk_app(family_id fid, decl_kind k, unsigned num_args, expr * const * args) {
    return mk_app(fid, k, 0, 0, num_args, args);
}

app * ast_manager::mk_app(family_id fid, decl_kind k, expr * arg) {
    return mk_app(fid, k, 0, 0, 1, &arg);
}

app * ast_manager::mk_app(family_id fid, decl_kind k, expr * arg1, expr * arg2) {
    expr * args[2] = { arg1, arg2 };
    return mk_app(fid, k, 0, 0, 2, args);
}

app * ast_manager::mk_app(family_id fid, decl_kind k, expr * arg1, expr * arg2, expr * arg3) {
    expr * args[3] = { arg1, arg2, arg3 };
    return mk_app(fid, k, 0, 0, 3, args);
}

sort * ast_manager::mk_sort(symbol const & name, sort_info * info) {
    unsigned sz      = sort::get_obj_size();
    void * mem       = allocate_node(sz);
    sort * new_node  = new (mem) sort(name, info); 
    return register_node(new_node);
}

sort * ast_manager::mk_uninterpreted_sort(symbol const & name, unsigned num_parameters, parameter const * parameters) {
    user_sort_plugin * plugin = get_user_sort_plugin();
    decl_kind kind = plugin->register_name(name);
    return plugin->mk_sort(kind, num_parameters, parameters);
}

func_decl * ast_manager::mk_func_decl(symbol const & name, unsigned arity, sort * const * domain, sort * range, 
                                      bool assoc, bool comm, bool inj) {
    func_decl_info info(null_family_id, null_decl_kind);
    info.set_associative(assoc);
    info.set_commutative(comm);
    info.set_injective(inj);
    return mk_func_decl(name, arity, domain, range, info);
}

func_decl * ast_manager::mk_func_decl(symbol const & name, unsigned arity, sort * const * domain, sort * range, func_decl_info * info) {
    SASSERT(arity == 1 || info == 0 || !info->is_injective());
    SASSERT(arity == 2 || info == 0 || !info->is_associative());
    SASSERT(arity == 2 || info == 0 || !info->is_commutative());
    unsigned sz               = func_decl::get_obj_size(arity);
    void * mem                = allocate_node(sz);
    func_decl * new_node = new (mem) func_decl(name, arity, domain, range, info);
    return register_node(new_node);
}

void ast_manager::check_sort(func_decl const * decl, unsigned num_args, expr * const * args) const {
    ast_manager& m = const_cast<ast_manager&>(*this);

    if (decl->is_associative()) {
        sort * expected = decl->get_domain(0);
        for (unsigned i = 0; i < num_args; i++) {
            sort * given = get_sort(args[i]);
            if (!compatible_sorts(expected, given)) {
                std::ostringstream buff;
                buff << "invalid function application for " << decl->get_name() << ", ";
                buff << "sort mismatch on argument at position " << (i+1) << ", ";
                buff << "expected " << mk_pp(expected, m) << " but given " << mk_pp(given, m);
                throw ast_exception(buff.str().c_str());
            }
        }
    }
    else {
        if (decl->get_arity() != num_args) {
            throw ast_exception("invalid function application, wrong number of arguments");
        }
        for (unsigned i = 0; i < num_args; i++) {
            sort * expected = decl->get_domain(i);
            sort * given    = get_sort(args[i]);
            if (!compatible_sorts(expected, given)) {
                std::ostringstream buff;
                buff << "invalid function application for " << decl->get_name() << ", ";
                buff << "sort mismatch on argument at position " << (i+1) << ", ";
                buff << "expected " << mk_pp(expected, m) << " but given " << mk_pp(given, m);
                throw ast_exception(buff.str().c_str());
            }
        }
    }
}

/**
   \brief Shallow sort checker. 
   Return true if success. 
   If n == 0, then fail.
   If n is an application, checks whether the arguments of n match the expected types.
*/
void ast_manager::check_sorts_core(ast const * n) const {
    if (!n) {
        throw ast_exception("expression is null");
    }
    if  (n->get_kind() != AST_APP) 
        return; // nothing else to check...
    app const * a = to_app(n);
    func_decl* d = a->get_decl();
    check_sort(d, a->get_num_args(), a->get_args());
    if (a->get_num_args() == 2 &&
        !d->is_flat_associative() && 
        d->is_right_associative()) {
        check_sorts_core(a->get_arg(1));
    }
    if (a->get_num_args() == 2 &&
        !d->is_flat_associative() && 
        d->is_left_associative()) {
        check_sorts_core(a->get_arg(0));
    }
}

bool ast_manager::check_sorts(ast const * n) const {
    try {
        check_sorts_core(n);
        return true;
    }
    catch (ast_exception & ex) {
        warning_msg(ex.msg());
        return false;
    }
}

bool ast_manager::compatible_sorts(sort * s1, sort * s2) const {
    if (s1 == s2)
        return true;
    if (m_int_real_coercions)
        return s1->get_family_id() == m_arith_family_id && s2->get_family_id() == m_arith_family_id;
    return false;
}

bool ast_manager::coercion_needed(func_decl * decl, unsigned num_args, expr * const * args) {
    SASSERT(m_int_real_coercions);
    if (decl->is_associative()) {
        sort * d = decl->get_domain(0);
        if (d->get_family_id() == m_arith_family_id) {
            for (unsigned i = 0; i < num_args; i++) {
                if (d != get_sort(args[i]))
                    return true;
            }
        }
    }
    else {
        if (decl->get_arity() != num_args) {
            // Invalid input: unexpected number of arguments for non-associative operator.
            // So, there is no point in coercing the input arguments.
            return false; 
        }
        for (unsigned i = 0; i < num_args; i++) {
            sort * d = decl->get_domain(i);
            if (d->get_family_id() == m_arith_family_id && d != get_sort(args[i]))
                return true;
        }
    }
    return false;
}

app * ast_manager::mk_app_core(func_decl * decl, unsigned num_args, expr * const * args) {
    app * r = 0;
    app * new_node = 0;
    unsigned sz = app::get_obj_size(num_args);
    void * mem = allocate_node(sz);

    try {                        
        if (m_int_real_coercions && coercion_needed(decl, num_args, args)) {
            expr_ref_buffer new_args(*this);
            if (decl->is_associative()) {
                sort * d = decl->get_domain(0);
                for (unsigned i = 0; i < num_args; i++) {
                    sort * s = get_sort(args[i]);
                    if (d != s && d->get_family_id() == m_arith_family_id && s->get_family_id() == m_arith_family_id) {
                        if (d->get_decl_kind() == REAL_SORT)
                            new_args.push_back(mk_app(m_arith_family_id, OP_TO_REAL, args[i]));
                        else
                            new_args.push_back(mk_app(m_arith_family_id, OP_TO_INT, args[i]));
                    }
                    else {
                        new_args.push_back(args[i]);
                    }
                }
            }
            else {
                for (unsigned i = 0; i < num_args; i++) {
                    sort * d = decl->get_domain(i);
                    sort * s = get_sort(args[i]);
                    if (d != s && d->get_family_id() == m_arith_family_id && s->get_family_id() == m_arith_family_id) {
                        if (d->get_decl_kind() == REAL_SORT)
                            new_args.push_back(mk_app(m_arith_family_id, OP_TO_REAL, args[i]));
                        else
                            new_args.push_back(mk_app(m_arith_family_id, OP_TO_INT, args[i]));
                    }
                    else {
                        new_args.push_back(args[i]);
                    }
                }
            }
            check_args(decl, num_args, new_args.c_ptr());
            SASSERT(new_args.size() == num_args);
            new_node = new (mem)app(decl, num_args, new_args.c_ptr());
            r = register_node(new_node);
        }
        else {
            check_args(decl, num_args, args);
            new_node = new (mem)app(decl, num_args, args);
            r = register_node(new_node);
        }

        if (m_trace_stream && r == new_node) {
            *m_trace_stream << "[mk-app] #" << r->get_id() << " ";
            if (r->get_num_args() == 0 && r->get_decl()->get_name() == "int") {
                ast_ll_pp(*m_trace_stream, *this, r);
            }
            else if (is_label_lit(r)) {
                ast_ll_pp(*m_trace_stream, *this, r);
            }
            else {
                *m_trace_stream << r->get_decl()->get_name();
                for (unsigned i = 0; i < r->get_num_args(); i++)
                    *m_trace_stream << " #" << r->get_arg(i)->get_id();
                *m_trace_stream << "\n";
            }
        }
    }
    catch (...) {
        deallocate_node(static_cast<ast*>(mem), sz);
        throw;
    }

    return r;
}

void ast_manager::check_args(func_decl* f, unsigned n, expr* const* es) {
    for (unsigned i = 0; i < n; i++) {
        sort * actual_sort   = get_sort(es[i]);
        sort * expected_sort = f->is_associative() ? f->get_domain(0) : f->get_domain(i);
        if (expected_sort != actual_sort) {
            std::ostringstream buffer;
            buffer << "Sort mismatch at argument #" << (i+1) 
                   << " for function " << mk_pp(f,*this) 
                   << " supplied sort is " 
                   << mk_pp(actual_sort, *this);
            throw ast_exception(buffer.str().c_str());            
        }
    }
}


inline app * ast_manager::mk_app_core(func_decl * decl, expr * arg1, expr * arg2) {
    expr * args[2] = { arg1, arg2 };
    return mk_app_core(decl, 2, args);
}

app * ast_manager::mk_app(func_decl * decl, unsigned num_args, expr * const * args) {
    bool type_error = 
        decl->get_arity() != num_args && !decl->is_right_associative() && 
        !decl->is_left_associative() && !decl->is_chainable();

    type_error |= (decl->get_arity() != num_args && num_args < 2 && 
                   decl->get_family_id() == m_basic_family_id && !decl->is_associative());

    if (type_error) {
        std::ostringstream buffer;
        buffer << "Wrong number of arguments (" << num_args 
               << ") passed to function " << mk_pp(decl, *this);        
        throw ast_exception(buffer.str().c_str());
    }
    app * r = 0;
    if (num_args > 2 && !decl->is_flat_associative()) {
        if (decl->is_right_associative()) {
            unsigned j = num_args - 1;
            r = mk_app_core(decl, args[j-1], args[j]);
            -- j;
            while (j > 0) {
                --j;
                r = mk_app_core(decl, args[j], r);
            }
        }
        else if (decl->is_left_associative()) {
            r = mk_app_core(decl, args[0], args[1]);
            for (unsigned i = 2; i < num_args; i++) {
                r = mk_app_core(decl, r, args[i]);
            }
        }
        else if (decl->is_chainable()) {
            TRACE("chainable", tout << "chainable...\n";);
            ptr_buffer<expr> new_args;
            for (unsigned i = 1; i < num_args; i++) {
                new_args.push_back(mk_app_core(decl, args[i-1], args[i]));
            }
            r = mk_and(new_args.size(), new_args.c_ptr());
        }
    }
    if (r == 0) {
        r = mk_app_core(decl, num_args, args);
    }
    SASSERT(r != 0);
    TRACE("app_ground", tout << "ground: " << r->is_ground() << "\n" << mk_ll_pp(r, *this) << "\n";);
    return r;
}



func_decl * ast_manager::mk_fresh_func_decl(symbol const & prefix, symbol const & suffix, unsigned arity, 
                                            sort * const * domain, sort * range) {
    func_decl_info info(null_family_id, null_decl_kind);
    info.m_skolem = true;
    SASSERT(info.is_skolem());
    func_decl * d;
    if (prefix == symbol::null && suffix == symbol::null) {
        d = mk_func_decl(symbol(m_fresh_id), arity, domain, range, &info);
    }
    else {
        string_buffer<64> buffer;
        buffer << prefix;
        if (prefix == symbol::null)
            buffer << "sk";
        buffer << "!";
        if (suffix != symbol::null)
            buffer << suffix << "!";
        buffer << m_fresh_id;
        d = mk_func_decl(symbol(buffer.c_str()), arity, domain, range, &info);
    }
    m_fresh_id++;
    SASSERT(d->get_info());
    SASSERT(d->is_skolem());
    return d;
}

sort * ast_manager::mk_fresh_sort(char const * prefix) {
    string_buffer<32> buffer;
    buffer << prefix << "!" << m_fresh_id;
    m_fresh_id++;
    return mk_uninterpreted_sort(symbol(buffer.c_str()));
}

symbol ast_manager::mk_fresh_var_name(char const * prefix) {
    string_buffer<32> buffer;
    buffer << (prefix ? prefix : "var") << "!" << m_fresh_id;
    m_fresh_id++;
    return symbol(buffer.c_str());
}

var * ast_manager::mk_var(unsigned idx, sort * s) {
    unsigned sz     = var::get_obj_size();
    void * mem      = allocate_node(sz);
    var * new_node  = new (mem) var(idx, s);
    return register_node(new_node);
}

app * ast_manager::mk_label(bool pos, unsigned num_names, symbol const * names, expr * n) {
    SASSERT(num_names > 0);
    SASSERT(get_sort(n) == m_bool_sort);
    buffer<parameter> p;
    p.push_back(parameter(static_cast<int>(pos)));
    for (unsigned i = 0; i < num_names; i++) 
        p.push_back(parameter(names[i]));
    return mk_app(m_label_family_id, OP_LABEL, p.size(), p.c_ptr(), 1, &n);
}

app * ast_manager::mk_label(bool pos, symbol const & name, expr * n) {
    return mk_label(pos, 1, &name, n);
}

bool ast_manager::is_label(expr const * n, bool & pos, buffer<symbol> & names) const {
    if (!is_app_of(n, m_label_family_id, OP_LABEL)) {
        return false;
    }
    func_decl const * decl = to_app(n)->get_decl();
    pos  = decl->get_parameter(0).get_int() != 0;
    for (unsigned i = 1; i < decl->get_num_parameters(); i++) 
        names.push_back(decl->get_parameter(i).get_symbol());
    return true;
}

app * ast_manager::mk_label_lit(unsigned num_names, symbol const * names) {
    SASSERT(num_names > 0);
    buffer<parameter> p;
    for (unsigned i = 0; i < num_names; i++) 
        p.push_back(parameter(names[i]));
    return mk_app(m_label_family_id, OP_LABEL_LIT, p.size(), p.c_ptr(), 0, 0);
}

app * ast_manager::mk_label_lit(symbol const & name) {
    return mk_label_lit(1, &name);
}

bool ast_manager::is_label_lit(expr const * n, buffer<symbol> & names) const {
    if (!is_app_of(n, m_label_family_id, OP_LABEL_LIT)) {
        return false;
    }
    func_decl const * decl = to_app(n)->get_decl();
    for (unsigned i = 0; i < decl->get_num_parameters(); i++) 
        names.push_back(decl->get_parameter(i).get_symbol());
    return true;
}

app * ast_manager::mk_pattern(unsigned num_exprs, app * const * exprs) {
    DEBUG_CODE({
            for (unsigned i = 0; i < num_exprs; ++i) {
                SASSERT(is_app(exprs[i]));
            }});
    return mk_app(m_pattern_family_id, OP_PATTERN, 0, 0, num_exprs, (expr*const*)exprs);
}

bool ast_manager::is_pattern(expr const * n) const {
    if (!is_app_of(n, m_pattern_family_id, OP_PATTERN)) {
        return false;
    }
    for (unsigned i = 0; i < to_app(n)->get_num_args(); ++i) {
        if (!is_app(to_app(n)->get_arg(i))) {
            return false;
         }
    }
    return true;
}

quantifier * ast_manager::mk_quantifier(bool forall, unsigned num_decls, sort * const * decl_sorts, symbol const * decl_names, 
                                        expr * body, int weight , symbol const & qid, symbol const & skid,
                                        unsigned num_patterns, expr * const * patterns, 
                                        unsigned num_no_patterns, expr * const * no_patterns) {
    SASSERT(body);
    SASSERT(num_patterns == 0 || num_no_patterns == 0);
    SASSERT(num_decls > 0);
    DEBUG_CODE({
            for (unsigned i = 0; i < num_patterns; ++i) {
                SASSERT(is_pattern(patterns[i]));
            }});
    unsigned sz               = quantifier::get_obj_size(num_decls, num_patterns, num_no_patterns);
    void * mem                = allocate_node(sz);
    quantifier * new_node = new (mem) quantifier(forall, num_decls, decl_sorts, decl_names, body,
                                                 weight, qid, skid, num_patterns, patterns,
                                                 num_no_patterns, no_patterns);
    quantifier * r = register_node(new_node);
              
    if (m_trace_stream && r == new_node) {
        *m_trace_stream << "[mk-quant] #" << r->get_id() << " " << qid;
        for (unsigned i = 0; i < num_patterns; ++i) {
            *m_trace_stream << " #" << patterns[i]->get_id();
        }
        *m_trace_stream << " #" << body->get_id() << "\n";
        
    }

    return r;
}

// Return true if the patterns of q are the given ones.
static bool same_patterns(quantifier * q, unsigned num_patterns, expr * const * patterns) {
    if (num_patterns != q->get_num_patterns())
        return false;
    for (unsigned i = 0; i < num_patterns; i++)
        if (q->get_pattern(i) != patterns[i])
            return false;
    return true;
}

// Return true if the no patterns of q are the given ones.
static bool same_no_patterns(quantifier * q, unsigned num_no_patterns, expr * const * no_patterns) {
    if (num_no_patterns != q->get_num_no_patterns())
        return false;
    for (unsigned i = 0; i < num_no_patterns; i++)
        if (q->get_no_pattern(i) != no_patterns[i])
            return false;
    return true;
}

quantifier * ast_manager::update_quantifier(quantifier * q, unsigned num_patterns, expr * const * patterns, expr * body) {
    if (q->get_expr() == body && same_patterns(q, num_patterns, patterns))
        return q;
    return mk_quantifier(q->is_forall(),
                         q->get_num_decls(),
                         q->get_decl_sorts(),
                         q->get_decl_names(),
                         body,
                         q->get_weight(),
                         q->get_qid(),
                         q->get_skid(),
                         num_patterns,
                         patterns,
                         num_patterns == 0 ? q->get_num_no_patterns() : 0,
                         num_patterns == 0 ? q->get_no_patterns() : 0);
}

quantifier * ast_manager::update_quantifier(quantifier * q, unsigned num_patterns, expr * const * patterns, unsigned num_no_patterns, expr * const * no_patterns, expr * body) {
    if (q->get_expr() == body && same_patterns(q, num_patterns, patterns) && same_no_patterns(q, num_no_patterns, no_patterns))
        return q;
    return mk_quantifier(q->is_forall(),
                         q->get_num_decls(),
                         q->get_decl_sorts(),
                         q->get_decl_names(),
                         body,
                         q->get_weight(),
                         q->get_qid(),
                         q->get_skid(),
                         num_patterns,
                         patterns,
                         num_no_patterns,
                         no_patterns);
}

quantifier * ast_manager::update_quantifier(quantifier * q, expr * body) {
    if (q->get_expr() == body)
        return q;
    return mk_quantifier(q->is_forall(),
                         q->get_num_decls(),
                         q->get_decl_sorts(),
                         q->get_decl_names(),
                         body,
                         q->get_weight(),
                         q->get_qid(),
                         q->get_skid(),
                         q->get_num_patterns(),
                         q->get_patterns(),
                         q->get_num_no_patterns(),
                         q->get_no_patterns());
}

quantifier * ast_manager::update_quantifier_weight(quantifier * q, int w) {
    if (q->get_weight() == w)
        return q;
    TRACE("update_quantifier_weight", tout << "#" << q->get_id() << " " << q->get_weight() << " -> " << w << "\n";);
    return mk_quantifier(q->is_forall(),
                         q->get_num_decls(),
                         q->get_decl_sorts(),
                         q->get_decl_names(),
                         q->get_expr(),
                         w,
                         q->get_qid(),
                         q->get_skid(),
                         q->get_num_patterns(),
                         q->get_patterns(),
                         q->get_num_no_patterns(),
                         q->get_no_patterns());
}

quantifier * ast_manager::update_quantifier(quantifier * q, bool is_forall, expr * body) {
    if (q->get_expr() == body && q->is_forall() == is_forall)
        return q;
    return mk_quantifier(is_forall,
                         q->get_num_decls(),
                         q->get_decl_sorts(),
                         q->get_decl_names(),
                         body,
                         q->get_weight(),
                         q->get_qid(),
                         q->get_skid(),
                         q->get_num_patterns(),
                         q->get_patterns(),
                         q->get_num_no_patterns(),
                         q->get_no_patterns());
}

quantifier * ast_manager::update_quantifier(quantifier * q, bool is_forall, unsigned num_patterns, expr * const * patterns, expr * body) {
    if (q->get_expr() == body && q->is_forall() == is_forall && same_patterns(q, num_patterns, patterns))
        return q;
    return mk_quantifier(is_forall,
                         q->get_num_decls(),
                         q->get_decl_sorts(),
                         q->get_decl_names(),
                         body,
                         q->get_weight(),
                         q->get_qid(),
                         q->get_skid(),
                         num_patterns,
                         patterns,
                         num_patterns == 0 ? q->get_num_no_patterns() : 0,
                         num_patterns == 0 ? q->get_no_patterns() : 0);
}

app * ast_manager::mk_distinct(unsigned num_args, expr * const * args) {
    return mk_app(m_basic_family_id, OP_DISTINCT, num_args, args);
}

app * ast_manager::mk_distinct_expanded(unsigned num_args, expr * const * args) {
    if (num_args < 2)
        return mk_true();
    if (num_args == 2)
        return mk_not(mk_eq(args[0], args[1]));
    ptr_buffer<expr> new_args;
    for (unsigned i = 0; i < num_args - 1; i++) {
        expr * a1 = args[i];
        for (unsigned j = i + 1; j < num_args; j++) {
            expr * a2 = args[j];
            new_args.push_back(mk_not(mk_eq(a1, a2)));
        }
    }
    app * r = mk_and(new_args.size(), new_args.c_ptr());
    TRACE("distinct", tout << "expanded distinct:\n" << mk_pp(r, *this) << "\n";);
    return r;
}

// -----------------------------------
//
// expr_dependency
//
// -----------------------------------

expr_dependency * ast_manager::mk_leaf(expr * t) {
    if (t == 0)
        return 0;
    else
        return m_expr_dependency_manager.mk_leaf(t); 
}

expr_dependency * ast_manager::mk_join(unsigned n, expr * const * ts) {
    expr_dependency * d = 0;
    for (unsigned i = 0; i < n; i++)
        d = mk_join(d, mk_leaf(ts[i]));
    return d;
}

void ast_manager::linearize(expr_dependency * d, ptr_vector<expr> & ts) {
    m_expr_dependency_manager.linearize(d, ts);
    remove_duplicates(ts);
}

// -----------------------------------
//
// Values
//
// -----------------------------------

app * ast_manager::mk_model_value(unsigned idx, sort * s) {
    parameter p[2] = { parameter(idx), parameter(s) };
    return mk_app(m_model_value_family_id, OP_MODEL_VALUE, 2, p, 0, static_cast<expr * const *>(0));
}

expr * ast_manager::get_some_value(sort * s, some_value_proc * p) {
    flet<some_value_proc*> l(m_some_value_proc, p);
    return get_some_value(s);
}

expr * ast_manager::get_some_value(sort * s) {
    expr * v = 0;
    if (m_some_value_proc)
        v = (*m_some_value_proc)(s);
    if (v != 0)
        return v;
    family_id fid = s->get_family_id();
    if (fid != null_family_id) {
        decl_plugin * p = get_plugin(fid);
        if (p != 0) {
            v = p->get_some_value(s);
            if (v != 0)
                return v;
        }
    }
    return mk_model_value(0, s);
}

bool ast_manager::is_fully_interp(sort const * s) const {
    if (is_uninterp(s))
        return false;
    family_id fid = s->get_family_id();
    SASSERT(fid != null_family_id);
    decl_plugin * p = get_plugin(fid);
    if (p != 0)
        return p->is_fully_interp(s);
    return false;
}

// -----------------------------------
//
// Proof generation
//
// -----------------------------------

proof * ast_manager::mk_proof(family_id fid, decl_kind k, unsigned num_args, expr * const * args) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(fid, k, num_args, args);
}

proof * ast_manager::mk_proof(family_id fid, decl_kind k, expr * arg) {
    return mk_proof(fid, k, 1, &arg);
}

proof * ast_manager::mk_proof(family_id fid, decl_kind k, expr * arg1, expr * arg2) {
    expr * args[2] = { arg1, arg2 };
    return mk_proof(fid, k, 2, args);
}

proof * ast_manager::mk_proof(family_id fid, decl_kind k, expr * arg1, expr * arg2, expr * arg3) {
    expr * args[3] = { arg1, arg2, arg3 };
    return mk_proof(fid, k, 2, args);
}

proof * ast_manager::mk_true_proof() {
    expr * f = mk_true();
    return mk_proof(m_basic_family_id, PR_TRUE, f);
}

proof * ast_manager::mk_asserted(expr * f) { 
    CTRACE("mk_asserted_bug", !is_bool(f), tout << mk_ismt2_pp(f, *this) << "\nsort: " << mk_ismt2_pp(get_sort(f), *this) << "\n";);
    SASSERT(is_bool(f));
    return mk_proof(m_basic_family_id, PR_ASSERTED, f); 
}

proof * ast_manager::mk_goal(expr * f) { 
    SASSERT(is_bool(f));
    return mk_proof(m_basic_family_id, PR_GOAL, f); 
}

proof * ast_manager::mk_modus_ponens(proof * p1, proof * p2) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(has_fact(p1));
    SASSERT(has_fact(p2));
    CTRACE("mk_modus_ponens", !(is_implies(get_fact(p2)) || is_iff(get_fact(p2)) || is_oeq(get_fact(p2))), 
           tout << mk_ll_pp(p1, *this) << "\n";
           tout << mk_ll_pp(p2, *this) << "\n";);
    SASSERT(is_implies(get_fact(p2)) || is_iff(get_fact(p2)) || is_oeq(get_fact(p2)));
    CTRACE("mk_modus_ponens", to_app(get_fact(p2))->get_arg(0) != get_fact(p1),
           tout << mk_pp(get_fact(p1), *this) << "\n" << mk_pp(get_fact(p2), *this) << "\n";);
    SASSERT(to_app(get_fact(p2))->get_arg(0) == get_fact(p1));
    if (is_reflexivity(p2))
        return p1;
    expr * f = to_app(get_fact(p2))->get_arg(1);
    if (is_oeq(get_fact(p2))) 
        return mk_app(m_basic_family_id, PR_MODUS_PONENS_OEQ, p1, p2, f);
    return mk_app(m_basic_family_id, PR_MODUS_PONENS, p1, p2, f);
}

proof * ast_manager::mk_reflexivity(expr * e) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_REFLEXIVITY, mk_eq(e, e)); 
}

proof * ast_manager::mk_oeq_reflexivity(expr * e) { 
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_REFLEXIVITY, mk_oeq(e, e)); 
}

proof * ast_manager::mk_commutativity(app * f) {
    SASSERT(f->get_num_args() == 2);
    app * f_prime = mk_app(f->get_decl(), f->get_arg(1), f->get_arg(0));
    return mk_app(m_basic_family_id, PR_COMMUTATIVITY, mk_eq(f, f_prime));
}

/**
   \brief Given a proof of p, return a proof of (p <=> true)
*/
proof * ast_manager::mk_iff_true(proof * pr) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(has_fact(pr));
    SASSERT(is_bool(get_fact(pr)));
    return mk_app(m_basic_family_id, PR_IFF_TRUE, pr, mk_iff(get_fact(pr), mk_true()));
}

/**
   \brief Given a proof of (not p), return a proof of (p <=> false)
*/
proof * ast_manager::mk_iff_false(proof * pr) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(has_fact(pr));
    SASSERT(is_not(get_fact(pr)));
    expr * p = to_app(get_fact(pr))->get_arg(0);
    return mk_app(m_basic_family_id, PR_IFF_FALSE, pr, mk_iff(p, mk_false()));
}

proof * ast_manager::mk_symmetry(proof * p) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    if (!p)
        return p;
    if (is_reflexivity(p))
        return p;
    if (is_symmetry(p))
        return get_parent(p, 0);
    SASSERT(has_fact(p));
    SASSERT(is_app(get_fact(p)));
    SASSERT(to_app(get_fact(p))->get_num_args() == 2);
    return mk_app(m_basic_family_id, PR_SYMMETRY, p, 
                  mk_app(to_app(get_fact(p))->get_decl(), to_app(get_fact(p))->get_arg(1), to_app(get_fact(p))->get_arg(0)));
}

proof * ast_manager::mk_transitivity(proof * p1, proof * p2) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    if (!p1)
        return p2;
    if (!p2)
        return p1;
    SASSERT(has_fact(p1));
    SASSERT(has_fact(p2));
    SASSERT(is_app(get_fact(p1)));
    SASSERT(is_app(get_fact(p2)));
    SASSERT(to_app(get_fact(p1))->get_num_args() == 2);
    SASSERT(to_app(get_fact(p2))->get_num_args() == 2);
    CTRACE("mk_transitivity", to_app(get_fact(p1))->get_decl() != to_app(get_fact(p2))->get_decl(),
           tout << mk_pp(get_fact(p1), *this) << "\n\n" << mk_pp(get_fact(p2), *this) << "\n";
           tout << mk_pp(to_app(get_fact(p1))->get_decl(), *this) << "\n";
           tout << mk_pp(to_app(get_fact(p2))->get_decl(), *this) << "\n";);
    SASSERT(to_app(get_fact(p1))->get_decl() == to_app(get_fact(p2))->get_decl() ||
            ((is_iff(get_fact(p1)) || is_eq(get_fact(p1))) && 
             (is_iff(get_fact(p2)) || is_eq(get_fact(p2)))) ||
            ( (is_eq(get_fact(p1)) || is_oeq(get_fact(p1))) &&
              (is_eq(get_fact(p2)) || is_oeq(get_fact(p2)))));
    CTRACE("mk_transitivity", to_app(get_fact(p1))->get_arg(1) != to_app(get_fact(p2))->get_arg(0),       
           tout << mk_pp(get_fact(p1), *this) << "\n\n" << mk_pp(get_fact(p2), *this) << "\n";
           tout << mk_bounded_pp(p1, *this, 5) << "\n\n";
           tout << mk_bounded_pp(p2, *this, 5) << "\n\n";
    );
    SASSERT(to_app(get_fact(p1))->get_arg(1) == to_app(get_fact(p2))->get_arg(0));
    if (is_reflexivity(p1))
        return p2;
    if (is_reflexivity(p2))
        return p1;
    // OEQ is compatible with EQ for transitivity.
    func_decl* f = to_app(get_fact(p1))->get_decl();
    if (is_oeq(get_fact(p2))) f = to_app(get_fact(p2))->get_decl();    
    return mk_app(m_basic_family_id, PR_TRANSITIVITY, p1, p2, mk_app(f, to_app(get_fact(p1))->get_arg(0), to_app(get_fact(p2))->get_arg(1)));
}

proof * ast_manager::mk_transitivity(proof * p1, proof * p2, proof * p3) {
    return mk_transitivity(mk_transitivity(p1,p2), p3);
}

proof * ast_manager::mk_transitivity(proof * p1, proof * p2, proof * p3, proof * p4) {
    return mk_transitivity(mk_transitivity(mk_transitivity(p1,p2), p3), p4);
}

proof * ast_manager::mk_transitivity(unsigned num_proofs, proof * const * proofs) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(num_proofs > 0);
    proof * r = proofs[0];
    for (unsigned i = 1; i < num_proofs; i++) 
        r = mk_transitivity(r, proofs[i]);
    return r;
}

proof * ast_manager::mk_transitivity(unsigned num_proofs, proof * const * proofs, expr * n1, expr * n2) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    if (fine_grain_proofs()) 
        return mk_transitivity(num_proofs, proofs);
    SASSERT(num_proofs > 0);
    if (num_proofs == 1)
        return proofs[0];
    DEBUG_CODE({
        for (unsigned i = 0; i < num_proofs; i++) {
            SASSERT(proofs[i]);
            SASSERT(!is_reflexivity(proofs[i]));
        }
    });
    ptr_buffer<expr> args;
    args.append(num_proofs, (expr**) proofs);
    args.push_back(mk_eq(n1,n2));
    return mk_app(m_basic_family_id, PR_TRANSITIVITY_STAR, args.size(), args.c_ptr());
}

proof * ast_manager::mk_monotonicity(func_decl * R, app * f1, app * f2, unsigned num_proofs, proof * const * proofs) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(f1->get_num_args() == f2->get_num_args());
    SASSERT(f1->get_decl() == f2->get_decl());
    ptr_buffer<expr> args;
    args.append(num_proofs, (expr**) proofs);
    args.push_back(mk_app(R, f1, f2));
    return mk_app(m_basic_family_id, PR_MONOTONICITY, args.size(), args.c_ptr());
}

proof * ast_manager::mk_congruence(app * f1, app * f2, unsigned num_proofs, proof * const * proofs) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(get_sort(f1) == get_sort(f2));
    sort * s    = get_sort(f1);
    sort * d[2] = { s, s };
    return mk_monotonicity(mk_func_decl(m_basic_family_id, get_eq_op(f1), 0, 0, 2, d), f1, f2, num_proofs, proofs);
}

proof * ast_manager::mk_oeq_congruence(app * f1, app * f2, unsigned num_proofs, proof * const * proofs) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(get_sort(f1) == get_sort(f2));
    sort * s    = get_sort(f1);
    sort * d[2] = { s, s };
    return mk_monotonicity(mk_func_decl(m_basic_family_id, OP_OEQ, 0, 0, 2, d), f1, f2, num_proofs, proofs);
}

proof * ast_manager::mk_quant_intro(quantifier * q1, quantifier * q2, proof * p) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    if (!p) {
        return 0;
    } 
    SASSERT(q1->get_num_decls() == q2->get_num_decls());
    SASSERT(has_fact(p));
    SASSERT(is_iff(get_fact(p)));
    return mk_app(m_basic_family_id, PR_QUANT_INTRO, p, mk_iff(q1, q2));
}

proof * ast_manager::mk_oeq_quant_intro(quantifier * q1, quantifier * q2, proof * p) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(q1->get_num_decls() == q2->get_num_decls());
    SASSERT(has_fact(p));
    SASSERT(is_oeq(get_fact(p)));
    return mk_app(m_basic_family_id, PR_QUANT_INTRO, p, mk_oeq(q1, q2));
}

proof * ast_manager::mk_distributivity(expr * s, expr * r) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_DISTRIBUTIVITY, mk_eq(s, r));
}

proof * ast_manager::mk_rewrite(expr * s, expr * t) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_REWRITE, mk_eq(s, t));
}

proof * ast_manager::mk_oeq_rewrite(expr * s, expr * t) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_REWRITE, mk_oeq(s, t));
}

proof * ast_manager::mk_rewrite_star(expr * s, expr * t, unsigned num_proofs, proof * const * proofs) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    ptr_buffer<expr> args;
    args.append(num_proofs, (expr**) proofs);
    args.push_back(mk_eq(s, t));
    return mk_app(m_basic_family_id, PR_REWRITE_STAR, args.size(), args.c_ptr());
}

proof * ast_manager::mk_pull_quant(expr * e, quantifier * q) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_PULL_QUANT, mk_iff(e, q));
}

proof * ast_manager::mk_pull_quant_star(expr * e, quantifier * q) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_PULL_QUANT_STAR, mk_iff(e, q));
}

proof * ast_manager::mk_push_quant(quantifier * q, expr * e) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_PUSH_QUANT, mk_iff(q, e));
}

proof * ast_manager::mk_elim_unused_vars(quantifier * q, expr * e) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_ELIM_UNUSED_VARS, mk_iff(q, e));
}

proof * ast_manager::mk_der(quantifier * q, expr * e) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_DER, mk_iff(q, e));
}

proof * ast_manager::mk_quant_inst(expr * not_q_or_i, unsigned num_bind, expr* const* binding) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    vector<parameter> params;
    for (unsigned i = 0; i < num_bind; ++i) {
        params.push_back(parameter(binding[i]));
        SASSERT(params.back().is_ast());
    }
    return mk_app(m_basic_family_id, PR_QUANT_INST, num_bind, params.c_ptr(), 1, & not_q_or_i);
}

bool ast_manager::is_quant_inst(expr const* e, expr*& not_q_or_i, ptr_vector<expr>& binding) const {
    if (is_quant_inst(e)) {
        not_q_or_i = to_app(e)->get_arg(0);
        func_decl* d = to_app(e)->get_decl();
        SASSERT(binding.empty());
        for (unsigned i = 0; i < d->get_num_parameters(); ++i) {
            binding.push_back(to_expr(d->get_parameter(i).get_ast()));
        }
        return true;
    }
    return false;
}

bool ast_manager::is_rewrite(expr const* e, expr*& r1, expr*& r2) const {
    if (is_rewrite(e)) {
        VERIFY (is_eq(to_app(e)->get_arg(0), r1, r2) ||
                is_iff(to_app(e)->get_arg(0), r1, r2));
        return true;
    }
    else {
        return false;
    }
}

proof * ast_manager::mk_def_axiom(expr * ax) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_DEF_AXIOM, ax);
}

proof * ast_manager::mk_unit_resolution(unsigned num_proofs, proof * const * proofs) {
    SASSERT(num_proofs >= 2);
    for (unsigned i = 0; i < num_proofs; i++) {
        SASSERT(has_fact(proofs[i]));
    }
    ptr_buffer<expr> args;
    args.append(num_proofs, (expr**) proofs);
    expr * fact;
    expr * f1 = get_fact(proofs[0]);
    expr * f2 = get_fact(proofs[1]);
    if (num_proofs == 2 && is_complement(f1, f2)) {
        fact = mk_false();
    }
    else {
        CTRACE("mk_unit_resolution_bug", !is_or(f1), tout << mk_pp(f1, *this) << " " << mk_pp(f2, *this) << "\n";);
        SASSERT(is_or(f1));
        ptr_buffer<expr> new_lits;
        app const * cls   = to_app(f1);
        unsigned num_args = cls->get_num_args();
#ifdef Z3DEBUG
        svector<bool> found;
#endif
        for (unsigned i = 0; i < num_args; i++) {
            expr * lit = cls->get_arg(i);
            unsigned j = 1;
            for (; j < num_proofs; j++) {
                expr const * _fact = get_fact(proofs[j]);
                if (is_complement(lit, _fact)) {
                    DEBUG_CODE(found.setx(j, true, false););
                    break;
                }
            }
            if (j == num_proofs)
                new_lits.push_back(lit);
        }
        DEBUG_CODE({
            for (unsigned i = 1; m_proof_mode == PGM_FINE && i < num_proofs; i++) {
                CTRACE("mk_unit_resolution_bug", !found.get(i, false), 
                       for (unsigned j = 0; j < num_proofs; j++) {
                           tout << mk_ll_pp(get_fact(proofs[j]), *this);
                       });
                SASSERT(found.get(i, false));
            }
        });
        switch (new_lits.size()) {
        case 0:
            fact = mk_false();
            break;
        case 1:
            fact = new_lits[0];
            break;
        default:
            fact = mk_or(new_lits.size(), new_lits.c_ptr());
            break;
        }
    }
    args.push_back(fact);
    proof * pr = mk_app(m_basic_family_id, PR_UNIT_RESOLUTION, args.size(), args.c_ptr());
    TRACE("unit_resolution", tout << "unit_resolution generating fact\n" << mk_ll_pp(pr, *this););
    return pr;
}

proof * ast_manager::mk_unit_resolution(unsigned num_proofs, proof * const * proofs, expr * new_fact) {
    TRACE("unit_bug", 
          for (unsigned i = 0; i < num_proofs; i++) tout << mk_pp(get_fact(proofs[i]), *this) << "\n";
          tout << "===>\n";
          tout << mk_pp(new_fact, *this) << "\n";);

    ptr_buffer<expr> args;
    args.append(num_proofs, (expr**) proofs);
    args.push_back(new_fact);
#ifdef Z3DEBUG
    expr * f1 = get_fact(proofs[0]);
    expr const * f2 = get_fact(proofs[1]);
    if (num_proofs == 2 && is_complement(f1, f2)) {
        SASSERT(is_false(new_fact));
    }
    else {
        SASSERT(is_or(f1));
        app * cls            = to_app(f1);
        unsigned cls_sz      = cls->get_num_args();
        CTRACE("cunit_bug", !(num_proofs == cls_sz || (num_proofs == cls_sz + 1 && is_false(new_fact))),
          for (unsigned i = 0; i < num_proofs; i++) tout << mk_pp(get_fact(proofs[i]), *this) << "\n";
          tout << "===>\n";
          tout << mk_pp(new_fact, *this) << "\n";);
        SASSERT(num_proofs == cls_sz || (num_proofs == cls_sz + 1 && is_false(new_fact)));
        unsigned num_matches = 0;
        for (unsigned i = 0; i < cls_sz; i++) {
            expr * lit = cls->get_arg(i);
            unsigned j = 1;
            for (; j < num_proofs; j++) {
                if (is_complement(lit, get_fact(proofs[j]))) {
                    num_matches++;
                    break;
                }
            }
            if (j == num_proofs) {
                CTRACE("unit_bug1", new_fact != lit, tout << mk_ll_pp(new_fact, *this) << "\n" << mk_ll_pp(lit, *this) << "\n";);
                SASSERT(new_fact == lit);
            }
        }
        SASSERT(num_matches == cls_sz || num_matches == cls_sz - 1);
        SASSERT(num_matches != cls_sz || is_false(new_fact));
    }
#endif 
    proof * pr = mk_app(m_basic_family_id, PR_UNIT_RESOLUTION, args.size(), args.c_ptr());
    TRACE("unit_resolution", tout << "unit_resolution using fact\n" << mk_ll_pp(pr, *this););
    return pr;
}

proof * ast_manager::mk_hypothesis(expr * h) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    return mk_app(m_basic_family_id, PR_HYPOTHESIS, h);
}

proof * ast_manager::mk_lemma(proof * p, expr * lemma) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(has_fact(p));
    CTRACE("mk_lemma", !is_false(get_fact(p)), tout << mk_ll_pp(p, *this) << "\n";);
    SASSERT(is_false(get_fact(p)));
    return mk_app(m_basic_family_id, PR_LEMMA, p, lemma);
}

proof * ast_manager::mk_def_intro(expr * new_def) {
    SASSERT(is_bool(new_def));
    return mk_proof(m_basic_family_id, PR_DEF_INTRO, new_def); 
}

proof * ast_manager::mk_apply_defs(expr * n, expr * def, unsigned num_proofs, proof * const * proofs) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    ptr_buffer<expr> args;
    args.append(num_proofs, (expr**) proofs);
    args.push_back(mk_oeq(n, def));
    return mk_app(m_basic_family_id, PR_APPLY_DEF, args.size(), args.c_ptr());
}

proof * ast_manager::mk_iff_oeq(proof * p) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    if (!p)
        return p;
    
    SASSERT(has_fact(p));
    SASSERT(is_iff(get_fact(p)) || is_oeq(get_fact(p)));
    if (is_oeq(get_fact(p)))
        return p;

    app * iff = to_app(get_fact(p));
    expr * lhs = iff->get_arg(0);
    expr * rhs = iff->get_arg(1);
    return mk_app(m_basic_family_id, PR_IFF_OEQ, p, mk_oeq(lhs, rhs));
}

bool ast_manager::check_nnf_proof_parents(unsigned num_proofs, proof * const * proofs) const {
    for (unsigned i = 0; i < num_proofs; i++) {
        if (!has_fact(proofs[i]))
            return false;
        if (!is_oeq(get_fact(proofs[i])))
            return false;
    }
    return true;
}

proof * ast_manager::mk_nnf_pos(expr * s, expr * t, unsigned num_proofs, proof * const * proofs) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    check_nnf_proof_parents(num_proofs, proofs);
    ptr_buffer<expr> args;
    args.append(num_proofs, (expr**) proofs);
    args.push_back(mk_oeq(s, t));
    return mk_app(m_basic_family_id, PR_NNF_POS, args.size(), args.c_ptr());
}

proof * ast_manager::mk_nnf_neg(expr * s, expr * t, unsigned num_proofs, proof * const * proofs) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    check_nnf_proof_parents(num_proofs, proofs);
    ptr_buffer<expr> args;
    args.append(num_proofs, (expr**) proofs);
    args.push_back(mk_oeq(mk_not(s), t));
    return mk_app(m_basic_family_id, PR_NNF_NEG, args.size(), args.c_ptr());
}

proof * ast_manager::mk_nnf_star(expr * s, expr * t, unsigned num_proofs, proof * const * proofs) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    ptr_buffer<expr> args;
    args.append(num_proofs, (expr**) proofs);
    args.push_back(mk_oeq(s, t));
    return mk_app(m_basic_family_id, PR_NNF_STAR, args.size(), args.c_ptr());
}

proof * ast_manager::mk_skolemization(expr * q, expr * e) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(is_bool(q));
    SASSERT(is_bool(e));
    return mk_app(m_basic_family_id, PR_SKOLEMIZE, mk_oeq(q, e));
}

proof * ast_manager::mk_cnf_star(expr * s, expr * t, unsigned num_proofs, proof * const * proofs) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    ptr_buffer<expr> args;
    args.append(num_proofs, (expr**) proofs);
    args.push_back(mk_oeq(s, t));
    return mk_app(m_basic_family_id, PR_CNF_STAR, args.size(), args.c_ptr());
}

proof * ast_manager::mk_and_elim(proof * p, unsigned i) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(has_fact(p));
    SASSERT(is_and(get_fact(p)));
    CTRACE("mk_and_elim", i >= to_app(get_fact(p))->get_num_args(), tout << "i: " << i << "\n" << mk_pp(get_fact(p), *this) << "\n";);
    SASSERT(i < to_app(get_fact(p))->get_num_args());
    expr * f = to_app(get_fact(p))->get_arg(i);
    return mk_app(m_basic_family_id, PR_AND_ELIM, p, f);
}

proof * ast_manager::mk_not_or_elim(proof * p, unsigned i) {
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    SASSERT(has_fact(p));
    SASSERT(is_not(get_fact(p)));
    SASSERT(is_or(to_app(get_fact(p))->get_arg(0)));
    app * or_app = to_app(to_app(get_fact(p))->get_arg(0));
    SASSERT(i < or_app->get_num_args());
    expr * c     = or_app->get_arg(i);
    expr * f;
    if (is_not(c))
        f = to_app(c)->get_arg(0);
    else
        f = mk_not(c);
    return mk_app(m_basic_family_id, PR_NOT_OR_ELIM, p, f);
}


proof * ast_manager::mk_th_lemma(
    family_id tid, 
    expr * fact, unsigned num_proofs, proof * const * proofs,
    unsigned num_params, parameter const* params
    ) 
{
    if (m_proof_mode == PGM_DISABLED) 
        return m_undef_proof;
    
    ptr_buffer<expr> args;
    vector<parameter> parameters;
    parameters.push_back(parameter(get_family_name(tid)));
    for (unsigned i = 0; i < num_params; ++i) {
        parameters.push_back(params[i]);
    }
    args.append(num_proofs, (expr**) proofs);
    args.push_back(fact);
    return mk_app(m_basic_family_id, PR_TH_LEMMA, num_params+1, parameters.c_ptr(), args.size(), args.c_ptr());
}

proof* ast_manager::mk_hyper_resolve(unsigned num_premises, proof* const* premises, expr* concl,
                                     svector<std::pair<unsigned, unsigned> > const& positions,
                                     vector<expr_ref_vector> const& substs) {
    ptr_vector<expr> fmls;
    SASSERT(positions.size() + 1 == substs.size());
    for (unsigned i = 0; i < num_premises; ++i) {
        TRACE("hyper_res", tout << mk_pp(premises[i], *this) << "\n";);
        fmls.push_back(get_fact(premises[i]));
    }    
    SASSERT(is_bool(concl));
    vector<parameter> params;
    for (unsigned i = 0; i < substs.size(); ++i) {
        expr_ref_vector const& vec = substs[i];
        for (unsigned j = 0; j < vec.size(); ++j) {
            params.push_back(parameter(vec[j]));
        }
        if (i + 1 < substs.size()) {
            params.push_back(parameter(positions[i].first));
            params.push_back(parameter(positions[i].second));
        }
    }
    TRACE("hyper_res", 
          for (unsigned i = 0; i < params.size(); ++i) {
              params[i].display(tout); tout << "\n";
          });
    ptr_vector<sort> sorts;
    ptr_vector<expr> args;
    for (unsigned i = 0; i < num_premises; ++i) {
        sorts.push_back(mk_proof_sort());
        args.push_back(premises[i]);
    }
    sorts.push_back(mk_bool_sort());
    args.push_back(concl);
    app* result = mk_app(m_basic_family_id, PR_HYPER_RESOLVE, params.size(), params.c_ptr(), args.size(), args.c_ptr());
    SASSERT(result->get_family_id() == m_basic_family_id);
    SASSERT(result->get_decl_kind() == PR_HYPER_RESOLVE);
    return result;
}

bool ast_manager::is_hyper_resolve(
    proof* p, 
    proof_ref_vector& premises,
    expr_ref& conclusion,
    svector<std::pair<unsigned, unsigned> > & positions,
    vector<expr_ref_vector> & substs) {
    if (!is_hyper_resolve(p)) {
        return false;
    }
    unsigned sz = p->get_num_args();
    SASSERT(sz > 0);
    for (unsigned i = 0; i + 1 < sz; ++i) {
        premises.push_back(to_app(p->get_arg(i)));
    }
    conclusion = p->get_arg(sz-1);
    func_decl* d = p->get_decl();
    unsigned num_p = d->get_num_parameters();
    parameter const* params = d->get_parameters();
    
    substs.push_back(expr_ref_vector(*this));
    for (unsigned i = 0; i < num_p; ++i) {
        if (params[i].is_int()) {
            SASSERT(i + 1 < num_p);
            SASSERT(params[i+1].is_int());
            unsigned x = static_cast<unsigned>(params[i].get_int());
            unsigned y = static_cast<unsigned>(params[i+1].get_int());
            positions.push_back(std::make_pair(x, y));
            substs.push_back(expr_ref_vector(*this));
            ++i;
        }
        else {
            SASSERT(params[i].is_ast());
            ast* a = params[i].get_ast();
            SASSERT(is_expr(a));
            substs.back().push_back(to_expr(a));                
        }
    }
    
    return true;
}


// -----------------------------------
//
// ast_mark
//
// -----------------------------------

bool ast_mark::is_marked(ast * n) const {
    if (is_decl(n)) 
        return m_decl_marks.is_marked(to_decl(n));
    else
        return m_expr_marks.is_marked(to_expr(n));
}

void ast_mark::mark(ast * n, bool flag) {
    if (is_decl(n))
        return m_decl_marks.mark(to_decl(n), flag);
    else
        return m_expr_marks.mark(to_expr(n), flag);
}

void ast_mark::reset() {
    m_decl_marks.reset();
    m_expr_marks.reset();
}

// -----------------------------------
//
// scoped_mark
//
// -----------------------------------

void scoped_mark::mark(ast * n, bool flag) {
    SASSERT(flag);
    mark(n);
}

void scoped_mark::mark(ast * n) {
    if (!ast_mark::is_marked(n)) {
        m_stack.push_back(n);
        ast_mark::mark(n, true);
    }
}

void scoped_mark::reset() {
    ast_mark::reset();
    m_stack.reset();
    m_lim.reset();
}
   
void scoped_mark::push_scope() {
    m_lim.push_back(m_stack.size());
}

void scoped_mark::pop_scope() {
    unsigned new_size = m_stack.size();
    unsigned old_size = m_lim.back();
    for (unsigned i = old_size; i < new_size; ++i) {
        ast_mark::mark(m_stack[i].get(), false);            
    }
    m_lim.pop_back();
    m_stack.resize(old_size);
}

void scoped_mark::pop_scope(unsigned num_scopes) {
    for (unsigned i = 0; i < num_scopes; ++i) {
        pop_scope();
    }
}
   
// Added by KLM for use in GDB

// show an expr_ref on stdout

void prexpr(expr_ref &e){
  std::cout << mk_pp(e.get(), e.get_manager()) << std::endl;
}

void ast_manager::show_id_gen(){
  std::cout << "id_gen: " << m_expr_id_gen.show_hash() << " " << m_decl_id_gen.show_hash() << "\n";
}
